JP2010280995A - Method for producing industrial polyester fiber - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a method for producing a polyester fiber that has a high spinning speed at break, high productivity, a little fluff occurrence, a high strength, a low load elongation (high coefficient of elasticity, high modulus), small variations of physical properties such as strength, elongation, etc., and a low dry heat shrinkage ratio. <P>SOLUTION: The method for producing a polyester fiber compring a poly(ethylene aromatic dicarboxylate ester) and having a strength at break of ≥4.0 cN/dtex includes using an ethylene glycol as a raw material having a<SP>14</SP>C concentration ratio based on a<SP>14</SP>C concentration in circulation carbon in 1950 as a standard (100%) of ≥11% in total carbon atoms contained in the poly(ethylene aromatic dicarboxylate ester) and having a<SP>14</SP>C concentration ratio based on a<SP>14</SP>C concentration in circulation carbon in 1950 as a standard (100%) of ≥80% and ≤100% in total carbon atoms contained in the ethylene glycol. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a polyester fiber having high strength, high dimensional stability, and high heat resistance, which is useful as a reinforcing fiber for industrial materials and the like, in particular, a fiber / polymer composite, and a method for producing the same.

  Polyester fibers have many excellent properties such as high strength, high Young's modulus, and heat-resistant dimensional stability, and are therefore used in a wide range of fields such as clothing and industrial use. In particular, reinforcing fibers such as fibers and polymer composites among industrial materials are required to have high strength and high heat resistance, and so far, modification by various methods has been proposed and developed.

  For example, an example in which a crosslinking component is added to polyester to improve heat resistance (for example, see Patent Document 1) and an example in which inorganic particles for reinforcing polyester fibers are added (for example, see Patent Document 2). It is disclosed. However, when such copolymerization components that disturb the crystal structure of polyester and inorganic particles are added, heat resistance and strength improvement effects can be seen, but generally a large amount of fluff is generated in the yarn making process, Defects exist in process characteristics such as frequent occurrence, and there has been a demand for higher performance of fibers by another approach. In addition, since the fiber properties obtained vary in response to the poor yarn-making properties, development of higher-performance polyester fibers has been demanded.

JP 2008-260804 A JP-A-2005-213689

  The object of the present invention is based on the background related to the performance required for the polyester fiber as described above, has a high spinning speed and high productivity, and has good yarn production, less fluffing, high strength and low load. An object of the present invention is to provide a method for producing a polyester fiber having a small variation in physical properties such as elongation (high elastic modulus, high modulus), strength, elongation, and load-carrying, and a small dry heat shrinkage.

  In order to solve the above-mentioned problems of the prior art, the inventor has conducted extensive studies on the modification of polyester, and as a result, ethylene glycol produced from biomass resources (hereinafter referred to as biomass) as a diol component constituting the polyester. It has been found that the use of polyester glycol (which may be described as ethylene glycol) makes it possible to produce polyester fibers with high strength, high dimensional stability, and high heat resistance with high process stability compared to the known polyester fiber production methods. The present invention has been completed.

That is, the subject of the present invention is a method for producing a polyester fiber having a breaking strength of 4.0 cN / dtex or more comprising poly (ethylene aromatic dicarboxylate ester),
The total carbon atoms contained in the poly (ethylene aromatic dicarboxylate ester), and a ¹⁴ C-concentration of circulating carbon in 1950 time reference (100%) and the ¹⁴ C concentration ratio is 11% or more,
The total carbon atoms contained in the ethylene glycol, prepared using ¹⁴ C-concentration standard (100%) and the ¹⁴ C concentration ratio is less 100% 80% ethylene glycol in the circulating carbon in 1950 times as the raw material This can be solved by a method for producing a polyester fiber. Hereinafter, when the ¹⁴ C concentration in the circulating carbon as of 1950 is the standard (100%) of all carbon atoms in a certain organic compound, the current ¹⁴ C concentration ratio contained in the organic compound is determined as the organic This is referred to as the “bioavailability” of the compound. The measurement principle and measurement method of this concentration ratio will be described later. Further, a fiber made of poly (ethylene aromatic dicarboxylate ester) having an intrinsic viscosity of 0.50 to 1.00 dL / g is preferable. The poly (ethylene aromatic dicarboxylate ester) is preferably polyethylene terephthalate (PET), polyethylene naphthalate (PEN), or polyethylene-2,6-naphthalenedicarboxylate. Furthermore, it is more preferable that the poly (ethylene aromatic dicarboxylate ester) is polyethylene terephthalate (PET) having a bioization rate of 16% or more or polyethylene naphthalate (PEN) having a bioization rate of 11% or more.

  According to the present invention, by using biomass ethylene glycol, it is possible to provide a polyester fiber that has high strength, high dimensional stability, and high heat resistance in the fiber production process, and has few variations in physical properties and fluff.

  The polyester polymer used in the polyester fiber of the present invention is made of poly (ethylene aromatic dicarboxylate ester) and has excellent properties as a rubber reinforcing fiber for industrial materials, particularly tire cords and transmission belts. A general-purpose polyester polymer is used. Among them, the main repeating unit of poly (ethylene aromatic dicarboxylate ester) is preferably any one selected from the group consisting of ethylene terephthalate and ethylene-2,6-naphthalate, and particularly excellent in physical properties. It is preferably made of polyethylene terephthalate suitable for mass production. As a main repeating unit of polyester, it is preferable that 80 mol% or more of the repeating unit is contained with respect to all dicarboxylic acid components constituting the polyester. Particularly preferred is a polyester containing 90 mol% or more. Moreover, if it is a small amount in the polyester polymer, it may be a copolymer containing an appropriate third component.

  For example, as the polyester polymer used in the present invention, terephthalic acid or naphthalene-2,6-dicarboxylic acid or a functional derivative thereof and a dihydroxy compound can be polymerized in the presence of a catalyst under appropriate reaction conditions. . In addition, a copolymerized polyester is synthesized by adding one or more appropriate third components before the completion of polymerization of the polyester. Here, the “functional derivative” is a functional group effective for forming an ester bond, and is a lower alkyl ester having 1 to 6 carbon atoms or a lower aryl ester having 6 to 8 carbon atoms of a carboxylic acid. Represents a functional group such as an acid halide of a carboxylic acid. The “ester-forming functional group” described later also represents the same type of functional group.

  Suitable third components include: (a) compounds having two ester-forming functional groups, for example, aliphatic dicarboxylic acids such as oxalic acid, succinic acid, adipic acid, sebacic acid, dimer acid; cyclopropanedicarboxylic acid, Cycloaliphatic dicarboxylic acids such as cyclobutanedicarboxylic acid and hexahydroterephthalic acid; aromatic dicarboxylic acids such as phthalic acid, isophthalic acid, naphthalene-2,7-dicarboxylic acid, diphenyldicarboxylic acid; diphenyl ether dicarboxylic acid, diphenylsulfone dicarboxylic acid, Dicarboxylic acids containing oxygen atoms in addition to aromatic rings and carboxylic acid groups such as diphenoxyethanedicarboxylic acid and sodium 3,5-dicarboxybenzenesulfonate; glycolic acid, p-oxybenzoic acid, p-oxyethoxybenzoic acid, etc. Oxycarboxylic acids of 1,2- Lopylene glycol, trimethylene glycol, diethylene glycol, tetramethylene glycol, hexamethylene glycol, neopentylene glycol, p-xylylene glycol (1,4-bis (hydroxymethyl) benzene), 1,4-cyclohexanedimethanol, bisphenol A P, p′-diphenoxysulfone, 1,4-bis (β-hydroxyethoxy) benzene, 2,2-bis (p-β-hydroxyethoxyphenyl) propane, polyalkylene glycol, p-phenylenebis (hydroxydimethyl) An oxy compound such as cyclohexane) or a functional derivative thereof; a compound having a high degree of polymerization derived from the carboxylic acid, oxycarboxylic acid, oxy compound or functional derivative thereof; or (b) one ester form. Compound having a functional group, for example, benzoic acid, benzoyl benzoic acid, benzyloxy benzoic acid, and the like methoxy polyalkylene glycol. Furthermore, (c) compounds having three or more ester-forming functional groups, such as glycerin, pentaerythritol, trimethylolpropane, tricarballylic acid, trimesic acid, trimellitic acid, etc., are substantially linear in polymer. It can be used within the range.

  The polyester fiber of the present invention is characterized by having a polyester bioification rate of 11% or more. When the bio-ization rate is low, the effect of reducing fuzz and yarn breakage is not exhibited in the polyester fiber manufacturing process described later. When the polyester is polyethylene terephthalate, the bioification rate of the polyester fiber is preferably 18% or more. Further, when the polyester is polyethylene-2,6-naphthalenedicarboxylate, the biotinylation ratio of the polyester is preferably 12% or more.

In the present invention, as described later bio rate over 11%, the concentration of ^{14 C} is a radioactive carbon was measured for the configuration the total carbon content, the concentration of the substance concentration of ^{14 C} is the reference 107. The case of 44 pMC is defined as 100% biotinylation rate, and the ratio to the reference concentration (107.44 pMC) is 11% or more. Biomass ethylene glycol is ethylene glycol produced from biomass resources, and refers to an ethylene glycol having a bioration ratio of 80% or more and 100% or less obtained by measurement by the method described below. Here, the biomass resource refers to a carbon-neutral organic resource derived from renewable organisms that uses solar energy and is generated from water and carbon dioxide, and refers to a resource excluding fossil resources.

  According to the present invention, biomass resources are classified into three types, waste, unused, and resource crops, based on the generation form. Specifically, biomass resources include cellulosic crops (pulp, kenaf, straw, rice straw, waste paper, papermaking residue, etc.), lignin, charcoal, compost, natural rubber, cotton, sugar cane, oil (rapeseed oil, cottonseed oil, soybean oil, Coconut oil, etc.), glycerol, carbohydrate crops (corn, potatoes, wheat, rice, cassava, etc.), bagasse, terpene compounds, pulp black liquor, food waste, wastewater sludge and the like. In addition, a method for producing a glycol compound from biomass resources is not particularly limited, but a biological treatment method utilizing the action of microorganisms such as fungi and bacteria, acid, alkali, catalyst, thermal energy, light energy, etc. Known methods such as a chemical treatment method used or a physical treatment method such as miniaturization, compression, microwave treatment, or electromagnetic wave treatment can be used.

  As a method for converting biomass resources into ethylene glycol, various production methods can be exemplified. The production method is not particularly limited, but first, a biological treatment method using the action of microorganisms such as fungi and bacteria from biomass resources, a chemical treatment method using acid, alkali, catalyst, thermal energy or light energy, etc. Alternatively, a known method such as a physical processing method such as miniaturization, compression, microwave treatment, or electromagnetic wave treatment is performed. Next, a method of purifying the products obtained by these production methods by further performing a hydrogen thermal decomposition reaction using a catalyst. As another production method, ethanol is produced from sugarcane, bagasse, carbohydrate crops and the like by a biological treatment method, and further purified through ethylene oxide. A method of producing by such a method and further purifying by a distillation operation or the like can also be employed.

  Alternatively, biomass resources can be converted into glycerol, sorbitol, xylitol, glycol, fructose, cellulose, etc., and a mixture of ethylene glycol and 1,2-propanediol can be produced by hydrogenolysis using a catalyst. To do. Alternatively, a method of producing ethanol from sugarcane, bagasse, carbohydrate crops, etc. by a biological treatment method and further producing a mixture of ethylene glycol, diethylene glycol and triethylene glycol through ethylene oxide, and the like can be mentioned.

In the present invention, the biogenic rate is based on the concentration of ¹⁴ C, which is radioactive carbon in the circulating carbon as of 1950, in all carbon atoms constituting ethylene glycol and polyester (this value is set as 100%). ^14C concentration ratio. The concentration of ¹⁴ C which is the radioactive carbon can be measured by the following measurement method (radiocarbon concentration measurement). That is, the concentration measurement of ¹⁴ C is carried out by an isotope of carbon (specifically, ¹² C, ¹³ C) contained in a sample to be analyzed by accelerator mass spectrometry (AMS) combining a tandem accelerator and a mass spectrometer. , ¹⁴ C.) is physically separated using an atomic weight difference by an accelerator, and the abundance of each isotope atom is measured.

In 1 mole of carbon atoms (6.02 × 10 ²³ ) there are about 6.02 × 10 ^{11 14} C, which is about one trillionth of a normal carbon atom. ¹⁴ C is called a radioisotope and its half-life regularly decreases at 5730 years. It takes 26,000 years for all of these to collapse. Therefore, fossil fuels such as coal, oil, and natural gas, which are considered to have passed over 26,000 years after carbon dioxide in the atmosphere has been taken into plants and immobilized, are initially fixed. All of the ¹⁴ C elements that were also included in the are collapsed. Therefore, in the 21st century, ^14C elements are not included in fossil fuels such as coal, oil, and natural gas. Therefore, chemical substances produced using these fossil fuels as a raw material do not contain any ¹⁴ C element. On the other hand, ¹⁴ C is a cosmic ray that undergoes a nuclear reaction in the atmosphere, is constantly generated, and balances with a decrease due to radiation decay. The amount of ¹⁴ C is constant in the earth's atmospheric environment.

On the other hand, if the carbon dioxide in the atmosphere has been immobilized incorporated such animals eat the plants and which in its captured state, ^{14 C} without newly replenished, half of ^{14 C} According to the period, the ¹⁴ C concentration decreases at a constant rate with time. For this reason, by analyzing the ¹⁴ C concentration in the glycol compound, it is possible to easily determine whether it is a fossil resource-based material or a biomass resource-based glycol compound. Also this ¹⁴ C concentration was ¹⁴ C-concentration in the circulating carbon in natural time 1950 with modern standard reference, it is common practice to use the criteria for the ¹⁴ C concentration is 100%. The current ¹⁴ C concentration measured in this way is about 110 pMC (percent modern carbon), and the plastic used as a sample is made of a 100% natural (biological) material. It is known that it exhibits a value of about 110 pMC. This value corresponds to the bio-ization rate 100% mentioned above. Meanwhile petroleum (fossil) when measuring the ^{14 C} concentration using a substance derived from shows almost 0PMC. This value corresponds to the bio-ization rate 0% mentioned above. Using these values, the mixing ratio of naturally derived system-fossil derived system can be calculated. Furthermore, it is preferable to use an oxalic acid standard issued by NIST (National Institute of Standards and Technology) as the standard standard reference for the ¹⁴ C concentration. The specific radioactivity of carbon in this oxalic acid ( ¹⁴ C radioactivity intensity per gram of carbon) is separated for each carbon isotope, corrected to a constant value for ¹³ C, and corrected for attenuation from 1950 AD to the measurement date The value subjected to is used as the standard ¹⁴ C concentration value.

The method for analyzing the ¹⁴ C concentration in a glycol compound first requires pretreatment of the glycol compound. Specifically, the carbon contained in the glycol compound is oxidized and converted into carbon dioxide. Further, the obtained carbon dioxide is separated from water and nitrogen, and the carbon dioxide is subjected to a reduction treatment and converted into graphite which is solid carbon. The obtained graphite is irradiated with a cation such as Cs ⁺ to generate carbon negative ions. Subsequently, the carbon ions are accelerated using a tandem accelerator, the charge is converted from negative ions to positive ions, and the orbits of ¹² C ³⁺ , ¹³ C ³⁺ , and ¹⁴ C ³⁺ are separated by a mass analyzing electromagnet, and ¹⁴ C ³⁺ Measure with an electrostatic analyzer.

  In the polyester, various additives such as matting agents such as titanium dioxide, heat stabilizers, antifoaming agents, color modifiers, flame retardants, antioxidants, ultraviolet absorbers, infrared absorbers, fluorescent agents Additives such as montmorillonite, bentonite, hectorite, plate-like iron oxide, plate-like calcium carbonate, plate-like boehmite, or carbon nanotubes are included as additives for whitening agents, plasticizers, impact agents, or reinforcing agents. It goes without saying.

  More specifically, a method for producing a polyester polymer used in the present invention can be described as a conventionally known method for producing a polyester polymer. That is, after an ester exchange reaction between a dialkyl ester of a dicarboxylic acid represented by dimethyl terephthalate (DMT) or naphthalene-2,6-dimethylcarboxylate (NDC) and biomass ethylene glycol as a diol component as an acid component. The product of this reaction can be produced by heating under reduced pressure to cause polycondensation reaction while removing excess diol component. Alternatively, it is esterified with terephthalic acid (TA) or 2,6-naphthalenedicarboxylic acid as an acid component and ethylene glycol as a diol component, and the resulting reaction product is subjected to reduced pressure while removing excess diol component in the same manner. Polyester can also be produced by a polycondensation reaction.

  The biolization rate of diol constituting the polyester, that is, biomass ethylene glycol used for producing the polyester fiber of the present invention, is preferably 80% or more and 100% or less. A biogenic rate of 80% or less is not preferable because it causes a reduction in the biogenic rate of the theoretically obtained polyester and the effect of reducing the fluff and yarn breakage of the polyester described later cannot be obtained. Biomass rate of biomass ethylene glycol used in the method for producing polyester fiber of the present invention is more preferably 90% or more.

  Furthermore, in the polyester of the present invention, it is desirable to use recycled terephthalic acid or recycled dimethyl terephthalate as a raw material as the above-mentioned terephthalic acid or dimethyl terephthalate. As countermeasures against environmental problems and fossil fuel depletion problems in recent years, it is possible to provide polyester with reduced environmental impact by recycled dimethyl terephthalate and biomass ethylene glycol.

  The recycled dimethyl terephthalate is, for example, a bis (2-hydroxyethyl) terephthalate produced by depolymerizing a polyester mainly composed of polyalkylene terephthalate using an alkylene glycol such as ethylene glycol in a depolymerization step. It represents a high-purity dialkyl terephthalic acid ester obtained by purifying the terephthalic acid dialkyl ester produced by adding an alcohol such as methanol to the above and performing a transesterification reaction. Alternatively, a polyalkylene terephthalate may be directly subjected to a depolymerization reaction using an alcohol (hydroxyalkyl compound) in a depolymerization step, and the resulting terephthalic acid dialkyl ester may be used. In these reaction steps, it is preferable to employ a step in which methanol is used as the alcohol and dimethyl terephthalate is obtained as the terephthalic acid dialkyl ester. In addition, recycled dimethyl terephthalate is used as a polyalkylene terephthalate in consideration of collecting and using polyester products on the market and collecting components other than dimethyl terephthalate. It is preferable to use ethylene glycol as the alkylene glycol used for depolymerization using polyethylene terephthalate, which is produced and distributed in large quantities in the market. The recycled terephthalic acid refers to terephthalic acid obtained by hydrolyzing the dimethyl terephthalate and purifying it.

  In the process of recycling dimethyl terephthalate, the transesterification catalyst used in the case of the method utilizing transesterification is not particularly limited, but generally used manganese, magnesium, titanium, zinc, aluminum, calcium Cobalt, sodium, lithium, and lead compounds can be used. Examples of such compounds include manganese, magnesium, titanium, zinc, aluminum, calcium, cobalt, sodium, lithium, lead oxide, acetate, carboxylate, hydride, alcoholate, halide, carbonate, sulfuric acid. A salt etc. can be mentioned. Of these, manganese, magnesium, zinc, titanium, and cobalt compounds are preferred, and manganese, magnesium, and zinc compounds are more preferred from the viewpoints of melt stability of polyester, hue, small amount of insoluble foreign matter in the polymer, and spinning stability. Moreover, these compounds may use 2 or more types together.

  Moreover, antimony, titanium, germanium, and an aluminum compound are preferable about the polymerization catalyst used when manufacturing polyester using the raw material obtained in this way. Examples of such compounds include antimony, titanium, germanium, aluminum oxides, acetates, carboxylates, hydrides, alcoholates, halides, carbonates, sulfates, and the like. Moreover, these compounds may use 2 or more types together. Among them, an antimony compound is particularly preferable in that it has excellent polymerization activity, solid phase polymerization activity, melt stability, and hue of the polyester, and the obtained fiber has high strength, excellent spinning properties and stretchability.

  In this invention, a phosphorus compound can be added so that it may contain 1-500 mmol% with respect to the mol of the acid component which comprises polyester in the arbitrary steps which manufacture polyester. The phosphorus compound is not particularly limited, and examples thereof include general phosphorus compounds used in polyesters such as phosphorous acid, phosphoric acid, trimethyl phosphate, phenylphosphonic acid, phenylphosphinic acid, and triethylphosphonoacetate. . The addition time of the phosphorus compound is preferably from the beginning to the end of the transesterification or esterification reaction in the production process of the polyester, more preferably from the end of the transesterification or esterification reaction to the polycondensation reaction step. Before the start of.

  The thus-polymerized polyester polymer used in the present invention has an intrinsic viscosity of the polyester chip immediately before spinning, by performing known melt polymerization or solid phase polymerization, so that polyethylene terephthalate is 0.80 to 1. In the case of 20 dL / g and polyethylene naphthalate, the range of 0.65 to 1.20 dL / g is preferable. When the intrinsic viscosity of the polyester chip is too low, it is difficult to increase the strength of the fiber after melt spinning. On the other hand, if the intrinsic viscosity is too high, the solid phase polymerization time is greatly increased and the production efficiency is lowered, which is not preferable from the industrial viewpoint. The intrinsic viscosity is preferably in the range of 0.90 to 1.10 dL / g for polyethylene terephthalate and 0.65 to 1.00 dL / g for polyethylene naphthalate, respectively. In addition, as an intrinsic viscosity at the time of setting it as the polyester fiber by the method mentioned later, it is in the range of 0.75-1.15 dL / g in the case of polyethylene terephthalate, and 0.60-1.00 dL / g in the case of polyethylene naphthalate. preferable.

  In order to produce the polyester fiber of the present invention, the polyester polymer thus obtained can be obtained by melt spinning. More specifically, the obtained polyester polymer can be melted at a temperature of 285 to 335 ° C., and a spinneret equipped with a capillary can be used for spinning. Moreover, it is preferable to pass through a heated spinning cylinder having a temperature equal to or higher than the molten polymer temperature immediately after discharging from the spinneret. The length of the heated spinning cylinder is preferably 10 to 500 mm. Since the polymer immediately after being discharged from the spinneret is easy to be oriented and single yarn breakage is likely to occur, it is preferable to use the heated spinning cylinder to delay the cooling.

  The spun yarn that has passed through the heated spinning cylinder is preferably cooled by blowing cold air of 30 ° C. or lower. Furthermore, it is preferable that it is a cold wind of 25 degrees C or less. Next, it is preferable to apply an oil agent to the cooled thread form. When the molten polymer is discharged from the spinneret and molded in this manner, the spinning speed is preferably 300 to 6000 m / min. Furthermore, as a forming method in the production method of the present invention, a method of further stretching after spinning is preferable from the viewpoint of high-efficiency production.

  In particular, the polyester fiber of the present invention is preferably spun at a high speed, and the spinning speed is preferably 1500 to 5500 m / min. In this case, the fiber obtained before drawing becomes a partially oriented yarn. When spinning at such a high speed and the fiber is highly oriented and crystallized, conventionally, the fiber is often broken at the spinning stage. However, in the present invention, it is presumed that the orientation crystallization progressed uniformly and the spinning defects could be reduced due to the effect of using the biomass ethylene glycol as a diol component of the polyester. As a result, it has been found that the spinning performance is greatly improved.

  The stretching condition is preferably 1.5 to 10 times after spinning. Thus, it is possible to obtain a drawn fiber with higher strength by drawing after spinning. Conventionally, even when spinning at a low magnification, there is often a portion where the strength is weak due to the defect of the crystal at the time of drawing. However, in the present invention, because of the presence of biomass ethylene glycol contained as a diol component of the polyester, fine crystals are uniformly formed in the crystallization by stretching, so that stretching defects are unlikely to occur and the fibers can be stretched at a high magnification. It has become possible to increase the strength.

  As a drawing method for obtaining the polyester fiber of the present invention, it may be wound once from a take-up roller and drawn by a so-called separate drawing method, or undrawn yarn is continuously supplied from the take-up roller to the drawing process. The so-called direct stretching method may be used for stretching. The stretching conditions are one-stage or multi-stage stretching, and the stretching load factor is preferably 60 to 95%. The drawing load factor is the ratio of the tension at the time of drawing to the tension at which the fiber actually breaks.

  The preheating temperature at the time of drawing is preferably carried out at a temperature not lower than 20 ° C. of the glass transition point of the polyester undrawn yarn and not higher than 20 ° C. lower than the crystallization start temperature. The stretching ratio depends on the spinning speed, but it is preferable to perform stretching at a stretching ratio that gives a stretching load factor of 60 to 95% with respect to the breaking stretch ratio. Further, in order to maintain the strength of the fiber and improve the dimensional stability, it is preferable to perform heat setting at a temperature from 170 ° C. to the melting point of the fiber or less in the drawing process. Furthermore, it is preferable that the heat setting temperature at the time of Enjin is in the range of 170 to 270 ° C.

  An isotope of an element is said to have almost the same electronic state and very close chemical properties. However, there are known examples in which the physical properties of the polymer differ due to different mass numbers. For example, in the case of polyethylene naphthalate containing deuterium, J. MACROMOL. SCI. -PHYS. B36 (2), 205-219 (1999). That is, depending on the content of the radioisotope, differences occur in the physical properties of the polymer, including differences in molecular weight and density.

In the production method of the present invention, by using biomass ethylene glycol as the diol component constituting the polyester polymer, the abundance of ¹² C, ¹³ C, and ¹⁴ C is changed, and the crystal growth in the spinning / drawing process is different. It is estimated that In other words, in order to suppress the coarse crystal growth that occurs during the melting and discharging from the spinneret and the drawing process, and to reduce the coarse crystals that become a defect in the yarn making process, the yarn breaking rate in each process is greatly reduced. It is considered that the physical properties of the resulting polyester fiber were improved. That is, in the present invention, it is considered that the effects as described above are exhibited by setting the bioization rate to 11% or more.

  Various attempts have been made to spin polyester fibers at a high speed conventionally. In the present invention, the use of biomass ethylene glycol, which is unique to the present invention, as a diol component that constitutes polyester makes a dramatic increase in spinning stability. And improved high speed spinning. Furthermore, since the yarn breakage hardly occurs, the practical draw ratio can be increased, and a polyester fiber with higher strength can be obtained. Furthermore, the polyester fiber of the present invention has little decrease in the intrinsic viscosity IVf of the fiber, has a very high breaking spinning speed, high strength, low unloading (high modulus), small variation in strength, and low dryness. Despite the yield of fibers, there are few fuzz defects, and the yarn-making property is also good.

The mechanism that exerts the effect of the present invention is not necessarily clear, but a small amount of ¹⁴ C present in biomass ethylene glycol reinforces the polyester polymer by suppressing crystal growth, which is a drawback in the spinning and stretching process, or This is considered to be because the concentration of stress on the defects was suppressed and the structural defects of the fibers were reduced. In addition, the polyester fiber of the present invention exhibits the effects of suppressing the coarse crystal growth by biomass ethylene glycol, improving the breaking spinning speed, reducing the fuzz defect, improving the yarn-making property, and reducing the variation in physical properties. It is thought that there is.

  The strength of the polyester fiber of the present invention obtained by the above production method is required to be 4.0 cN / dtex or more, and preferably 4.0 to 10.0 cN / dtex. Furthermore, it is preferably 5.0 to 9.5 cN / dtex. When the strength is too low, the durability tends to be inferior when the strength is too high. In addition, when production is performed with a very high strength, yarn breakage tends to occur in the yarn making process, and there is a tendency for quality stability as an industrial fiber. In the case where the strength of the obtained polyester fiber is less than 4.0 cN, the range of applicable uses is narrow as the fiber for industrial material targeted by the present invention, and the usefulness tends to be low.

  The dry heat shrinkage at 180 ° C. is preferably 1.0 to 15.0%. If the dry heat shrinkage is too high, the dimensional change during processing tends to be large, and the dimensional stability of a molded product using fibers tends to be poor. Although there is no limitation in particular in the single yarn fineness of the polyester fiber obtained, it is preferable that it is 0.1-100 dtex / filament from a viewpoint of yarn-making property. Particularly, rubber reinforcing fibers such as tire cords and V-belts and industrial material fibers are preferably 1 to 20 dtex / filament from the viewpoint of strength, heat resistance and adhesiveness. The total fineness is not particularly limited, but is preferably 10 to 10,000 dtex, and particularly preferably 250 to 6,000 dtex for rubber reinforcing fibers such as tire cords and V-belts and fibers for industrial materials. . In addition, as the total fineness, for example, 2 to 10 yarns may be spun during spinning or drawing, or after the end of each, so that two fibers of 1,000 dtex are combined to a total fineness of 2,000 dtex. preferable. A person skilled in the art can obtain a polyester fiber having the above-described strength and dry heat shrinkage by appropriately adjusting the intrinsic viscosity, spinning speed, and draw ratio of the polyester before melt spinning.

  Furthermore, it is also preferable that the polyester fiber of the present invention is a cord in which the above-described polyester fiber is multifilament and twisted. By twisting the multifilament fiber, the strength utilization rate is averaged and the fatigue property is improved. The number of twists is preferably in the range of 50 to 1000 turns / m, and it is also preferable that the cord is a combined yarn obtained by performing a lower twist and an upper twist. The number of filaments constituting the yarn before being combined is preferably 50 to 3000. By using such a multifilament, fatigue resistance and flexibility are further improved. When the fineness is too small, the strength tends to be insufficient. On the other hand, if the fineness is too large, it becomes too thick and flexibility cannot be obtained, and sticking between single yarns tends to occur during spinning, and it tends to be difficult to produce stable fibers.

  In the method for producing a polyester fiber of the present invention, a desired fiber cord can be obtained by further twisting or combining the obtained fibers. Furthermore, it is also preferable to apply an adhesive treatment agent to the surface. As the adhesion treatment agent, treatment with an RFL adhesion treatment agent is optimal for rubber reinforcement applications.

  More specifically, such a fiber cord can be obtained by adding twisted yarn according to a conventional method to the above-mentioned polyester fiber, or attaching an RFL treatment agent in a non-twisted state, and performing heat treatment. Such a fiber becomes a treatment cord which can be suitably used for rubber reinforcement.

  The present invention will be further described in the following examples, but the scope of the present invention is not limited by these examples. Various characteristics were measured by the following methods. In addition, “biomass-derived ethylene glycol” used in each example refers to EG having a bio-ization rate of 100%.

(1) Intrinsic viscosity (IV):
A dilute solution obtained by dissolving a polyester chip sample or a polyester fiber sample in orthochlorophenol at 100 ° C. for 60 minutes was determined from the value measured at 35 ° C. using an Ubbelohde viscometer. Hereinafter referred to as IV.

(2) Diethylene glycol (DEG) content:
The polyester chip was decomposed using hydrazine hydrate (hydrated hydrazine), and the content of diethylene glycol in the decomposition product was measured using gas chromatography (manufactured by Hewlett-Packard (HP 6850)).

(3) Evaluation of bio-ization rate ( ^14C concentration measurement)
Concentration measurement of ¹⁴ C, by accelerator mass spectrometry in combination with tandem accelerator mass spectrometer, the concentration of ¹⁴ C is a radioactive carbon was measured for the configuration the total carbon content, in the case of 107.44pMC bio rate of 100% As a reference, the bioavailability was determined as the concentration ratio for this value.

(4) Strong elongation of fiber and intermediate unloading,
It measured according to JIS-L-1013 using the tensile load measuring device (Shimadzu Corporation autograph). In addition, intermediate | middle unloading represented the elongation at the time of load 4cN / dtex. An average value obtained by measuring 50 points was obtained, and a standard deviation σ (sigma) representing variation in each physical property was calculated.

(5) Dry heat shrinkage rate In accordance with JIS-L-1013, after leaving for 24 hours in a room where the temperature and humidity are controlled at 20 ° C. and 65% RH, heat treatment is performed in a dryer at 180 ° C. for 30 minutes, before and after heat treatment. It was calculated from the test length difference.

(6) Fluff defect of product The following evaluation was made according to the fuzz defect due to single yarn breakage in the appearance inspection of the wound fiber product.
○: Slight fluff defects are observed but good △: Slight fluff is present and product loss is slightly high

(7) Spinnability Evaluation was made below according to the number of yarn breaks per ton of the wound fiber product.
○: Less than 0.5 times / ton Δ: 0.5 times or more and less than 1.0 times / ton

[Example 1]
-Manufacture of polyester chips Manganese acetate-Tetrawater in a mixture of 194.2 parts by mass of dimethyl terephthalate (DMT) manufactured and purified from fossil fuel and 124.2 parts by mass of ethylene glycol derived from biomass (200 mol% compared to DMT) 0.0735 parts by mass (compared to DMT of 30 mmol%) of Japanese product was charged into a reactor equipped with a stirrer, a rectifying column and a methanol distillation condenser, and generated as a result of the reaction while gradually raising the temperature from 140 ° C to 240 ° C. The transesterification was carried out while distilling methanol to be distilled out of the reactor. Thereafter, 0.0246 parts by mass of phosphorous acid (30 mmol% relative to DMT) was added to complete the transesterification reaction. Thereafter, 0.0964 parts by mass of antimony trioxide (33 mmol% relative to DMT) was added to the reaction product, transferred to a reaction vessel equipped with a stirrer, a nitrogen inlet, a vacuum port and a distillation apparatus, and the temperature was raised to 290 ° C. , A polycondensation reaction was performed at a high vacuum of 30 Pa or less to obtain a polyester. Further, it was made into a chip according to a conventional method.
The polymer obtained had an IV of 0.63 dL / g and a biotinylation rate of 18%.

-Production of polyester fiber The obtained polyester chip was dried and pre-crystallized in a nitrogen atmosphere at 160 ° C for 3 hours, and further subjected to a solid-phase polymerization reaction at 230 ° C under vacuum to have an intrinsic viscosity of 1.02 dL / g. A polyethylene terephthalate chip was obtained.
This was spun from a spinneret with a diameter of 1.0 mm and a diameter of 250 holes at a polymer melting temperature of 296 ° C., passed through a cylindrical heating zone heated to 300 ° C. with a length of 200 mm provided immediately below the die, and then a blow-off distance of 500 mm. Cooling air from a cylindrical chimney adjusted to 20 ° C. and 65% RH is blown onto the spun yarn and cooled. Further, an oil agent mainly composed of an aliphatic ester compound has a fiber oil agent adhesion amount of 0.5%. After applying the oil agent, the film was taken up at a speed of 2500 m / min with a roller having a surface temperature of 50 ° C.
Further, the speed at which the take-up roller speed was increased and the speed at which the spun yarn was broken was measured as the breaking spinning speed.
The discharge yarn spun at a speed of 2500 m / min is continuously wound without being wound once, and then the first stage drawing is performed 1.4 times with the first roller having a surface temperature of 60 ° C. 1.15 times the second stage stretching with the two rollers, 1.4 times the third stage stretching with the third roller, and running yarn on the third roller with a surface temperature of 190 ° C The strip was wound and subjected to heat setting for 0.2 seconds, taken up at a constant length on a cooling roller, and then wound up at a winding speed of 5000 m / min to obtain a polyester fiber.
The resulting polyester fiber has little decrease in intrinsic viscosity (IVf), very high breaking spinning speed, high strength, low unloading (high modulus), small variation in strength, and low dry yield fiber. However, there were few fuzz defects and the yarn production was good. Table 2 shows the physical properties and process passability of the fibers.

[Example 2]
In Example 1, instead of dimethyl terephthalate purified from fossil fuel, the polyethylene terephthalate product was heated and depolymerized in the presence of ethylene glycol, and then changed to dimethyl terephthalate obtained by reacting with methanol. Except for this, the same procedure as in Example 1 was carried out to obtain a polyester polymer. The results are also shown in Table 1.
Further, melt spinning and stretching were performed in the same manner as in Example 1 to obtain a polyester fiber. The resulting fiber has a low decrease in intrinsic viscosity IVf, a very high breaking spinning speed, high strength, low unloading (high modulus), small variation in strength, and low dry yield of fibers. There were few, and the yarn-making property was also favorable. The results are also shown in Table 2.

[Example 3]
A slurry composed of 166.13 parts by mass of terephthalic acid and 74.4 parts by mass of ethylene glycol derived from biomass was supplied to a polycondensation tank, and an esterification reaction was performed at 250 ° C. under normal pressure. After preparing (β-hydroxyethyl) terephthalate and its low polymer, 0.00280 parts by mass of trimethyl phosphate (2 mmol% relative to TA) was added and stirred for 5 minutes, and then 0.0964 parts by mass of antimony trioxide (TA 33 mmol%) and transferred to a reaction vessel equipped with a stirrer, a nitrogen inlet, a vacuum port, and a distillation device, heated to 290 ° C., and subjected to a polycondensation reaction at a high vacuum of 30 Pa or less. Obtained. Further, it was made into a chip according to a conventional method. The results are also shown in Table 1.
Further, melt spinning and stretching were performed in the same manner as in Example 1 to obtain a polyester fiber. The resulting fiber has a low decrease in intrinsic viscosity IVf, a very high breaking spinning speed, high strength, low unloading (high modulus), small variation in strength, and low dry yield of fibers. There were few, and the yarn-making property was also favorable. The results are also shown in Table 2.

[Comparative Example 1]
In Example 1, it carried out like Example 1 except having used ethylene glycol manufactured from the conventional fossil resource instead of biomass-derived ethylene glycol, and refined, and obtained the polyester polymer.
Further, melt spinning and stretching were performed in the same manner as in Example 1 to obtain a polyester fiber. The results are also shown in Table 2.

[Example 4]
Manufacture of polyester chip 0.030 parts by mass of manganese acetate tetrahydrate was added to a mixture of 100 parts by mass of dimethyl 2,6-naphthalenedicarboxylate and 50 parts by mass of ethylene glycol derived from biomass. A transesterification reaction was performed while charging the reactor provided with a condenser and gradually raising the temperature from 150 ° C. to 245 ° C. while distilling methanol produced as a result of the reaction out of the reactor. Thereafter, 0.023 parts by mass of trimethyl phosphate was added to complete the transesterification reaction. Thereafter, 0.024 parts by mass of diantimony trioxide is added to the reaction product, transferred to a reaction vessel equipped with a stirrer, a nitrogen inlet, a vacuum port and a distillation device, heated to 305 ° C., and 30 Pa or less. A condensation polymerization reaction was performed in a high vacuum to obtain a polyester having an intrinsic viscosity of 0.65 dL / g, a diethylene glycol content of 0.6% by mass, and a biotinylation ratio of 14%. Further, it was made into a chip according to a conventional method.

-Manufacture of polyester fiber The obtained polyester chip was dried and pre-crystallized at 180 ° C for 3 hours under a nitrogen atmosphere, and further subjected to a solid phase polymerization reaction at 230 ° C under vacuum to have an intrinsic viscosity of 0.75 dL / g A polyethylene terephthalate chip was obtained.
This was spun from a spinneret of 0.27 mm and 24 holes at a polymer melting temperature of 300 ° C., taken up by a roller at a speed of 500 m / min, and wound up. Next, the film is stretched 5.1 times with a second roller having a surface temperature of 160 ° C., a running yarn is wound on a roller having a surface temperature of 240 ° C., and heat setting is performed for 60 seconds. After taking up, the fiber was wound up to obtain a polyester fiber.
The obtained fiber has a small decrease in intrinsic viscosity IVf, high strength, low unloading (high modulus), small variation in strength, and low dry yield fiber has few fuzz defects and good spinning properties. It was.

  The polyester fiber of the present invention thus obtained has a high quality with less defects such as coarse crystals, less physical property variations and fluff generation due to the different isotope abundance ratios of the diol components constituting the polyester. Since it is a polyester fiber that can be produced with high efficiency, it is very useful for a wide range of industrial material applications such as woven and knitted fabrics for industrial materials such as seat belts, tarpaulins, fish nets, ropes, and monofilaments.

  Further, it is also preferable to use in combination with a polymer to form a fiber / polymer composite. Particularly, it is suitably used as a rubber reinforcing fiber in which the polymer is a rubber elastic body, and is optimal for tires, belts, hoses, etc. is there.

Claims (4)

A method for producing a polyester fiber having a breaking strength of 4.0 cN / dtex or more comprising poly (ethylene aromatic dicarboxylate ester),
The total carbon atoms contained in the poly (ethylene aromatic dicarboxylate ester), and a ¹⁴ C-concentration of circulating carbon in 1950 time reference (100%) and the ¹⁴ C concentration ratio is 11% or more,
The total carbon atoms contained in the ethylene glycol, prepared using ¹⁴ C-concentration standard (100%) and the ¹⁴ C concentration ratio is less 100% 80% ethylene glycol in the circulating carbon in 1950 times as the raw material A method for producing a polyester fiber, comprising:   The method for producing a polyester fiber according to claim 1, wherein the poly (ethylene aromatic dicarboxylate ester) is polyethylene terephthalate.   The method for producing a polyester fiber according to claim 2, wherein the polyethylene terephthalate uses, as a raw material, a dialkyl ester of terephthalic acid obtained by a process including a depolymerization process of polyalkylene terephthalate.   The method for producing a polyester fiber according to claim 1, wherein the poly (ethylene aromatic dicarboxylate ester) is polyethylene-2,6-naphthalenedicarboxylate.