JP2007126780A - Polylactic acid-based conjugate fiber, and non-woven fabric and cushioning material using the same - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a polylactic acid-based conjugate fiber having a small heat shrinkage, excellent in initial bulk, further excellent in bulk recovery, and having flexibility and elasticity, and a non-woven fabric and a cushioning material using the same. <P>SOLUTION: This conjugate fiber includes a first component containing a poly-L-lactic acid having ≥165°C melting point and a second component containing an aliphatic polyester containing a recurring unit consisting of at least one aliphatic dicarboxylic acid component selected from succinic acid, etc. having a melting point of 100-130°C, and at least one glycol component selected from propylene glycol, etc., and conjugate-spinning them so as to expose the second component by ≥20% of the fiber surface. The conjugate fiber has the single fiber dry heat shrinkage measured according to the JIS-L-1015 and satisfying the following (1) and (2) physical values. (1) The single fiber dry heat shrinkage at a temperature of 80°C, for 15 min and at an initial load of 0.018 mN/dtex(2 mg/d) is <2%. (2)The single fiber dry heat shrinkage at a temperature of 120°C, for 15 min and at the initial load is <3%. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a polylactic acid-based composite fiber suitable for a non-woven fabric that has small heat shrinkage, is flexible and is excellent in bulkiness, and is also excellent in bulk elasticity, and a non-woven fabric and a cushion material using the same.

  Various fibers using biodegradable fibers and biomass-derived resins have been proposed as environmentally friendly fibers. In particular, various fibers using a polylactic acid resin as a biomass resin have been proposed. And since this is mainly used as a heat bondable fiber, the proposal of the composite fiber is also made | formed. As the required performance of the composite fiber, firstly, the shrinkage during thermal processing is small. Also, when crimping the composite fiber to make a card web or air laid web and then trying to obtain a heat-bonded nonwoven fabric by hot air processing, the bulk after heat processing is large, and also bulk elasticity, that is, bulk recovery in the thickness direction It is considered to be a good non-woven fabric with excellent properties. However, a composite fiber using a polylactic acid resin has not yet been obtained that satisfies the above characteristics.

  When heat-bonding the sheath component of the composite fiber to obtain a non-woven fabric, if the heat shrinkage of the fiber is large, the formation is disturbed, or the heat-bonded non-woven fabric obtained by hot air processing as described above, It is necessary that the heat shrinkability of the fiber is small because it is coarse and hard, bulky, and it is not possible to obtain a bulky and flexible nonwoven fabric with good texture.

  On the other hand, even if the heat shrinkability is small, if the core component, the sheath component, or a combination thereof is poor, there is a problem that the heat processing becomes bulky or coarse, and the bulk elasticity is low. It was.

In Patent Document 1 below, a thermoplastic resin mainly composed of polylactic acid having a melting point of 120 ° C. or higher is a core component, a melting point of 30 ° C. lower than that of the core component, and a thermoplastic resin having a melting point of 90 ° C. or higher is a sheath component. Biodegradable composite fibers have been proposed. Patent Document 2 proposes a composite short fiber composed of two types of polylactic acid polymers having different optical purities. Patent Document 3 discloses a thermobonding fiber in which a polyester mainly composed of L-lactic acid, which is spot-bonded to a base fiber made of an aliphatic polyester having a melting point of 130 ° C. or higher, is exposed on at least a part of the fiber surface. Proposed. Patent Document 4 discloses a polylactic acid polymer in which a core part forms a stereocomplex with a melting start temperature of 180 ° C. or higher, and a sheath part is a heat composed of an aliphatic polyester that is 30 ° C. lower than the melting point of the core part. Adhesive fibers have been proposed.
JP 7-133511 A JP 2001-49533 A JP 2000-226733 A (Claim 7) JP 2003-342836 A

  However, in the said patent document 1, the nonwoven fabric area shrinkage rate at the time of heat processing is 3% or more (for example, 3.6% in Example 1), and it was not enough to suppress heat shrinkage. Moreover, the bulk and bulk recoverability of the obtained nonwoven fabric were not taken into consideration and were not sufficient.

In Patent Document 2, the thermal shrinkage rate at 80 ° C. is as low as 2%, but the area shrinkage rate at the actual processing temperature is at least 11%, which is insufficient for practical use. Furthermore, the bulkiness of the nonwoven fabric was not as low as 28 cm ³ / g at most. Therefore, only a coarse and hard nonwoven fabric with poor formation and low bulk is obtained.

  In Patent Document 3, the thermal shrinkage at a temperature (180 ° C.) corresponding to the heat bonding process is as small as 8.0%, and a satisfactory nonwoven fabric cannot be obtained.

  In Patent Document 4, it is necessary to mix L-type polylactic acid and D-type polylactic acid in order to obtain a stereo complex, and physical properties tend to vary, making it difficult to obtain uniform fibers. Moreover, since it is necessary to prepare two types of different polymers, the polymers are expensive and not economical. In addition, if the melting point of the core component becomes too large, it is necessary to increase the stretching temperature in order to crystallize polylactic acid. However, if the melting point of the sheath component is low, the stretching temperature cannot be increased. As a result, polylactic acid was insufficiently crystallized, and only fibers having a large heat shrinkage rate were obtained.

  In order to solve the above-mentioned conventional problems, the present invention has a small thermal shrinkage, excellent initial bulk, excellent bulk recoverability, and is flexible and elastic compared to a conventional composite fiber using polylactic acid. A lactic acid-based composite fiber and a nonwoven fabric and cushion material using the same are provided.

  The polylactic acid-based composite fiber of the present invention includes at least one selected from a first component containing poly L-lactic acid having a melting point of 165 ° C. or higher, and succinic acid, adipic acid, and oxalic acid having a melting point of 100 to 130 ° C. An aliphatic dicarboxylic acid component and a second component comprising an aliphatic polyester comprising a repeating unit comprising at least one glycol component selected from ethylene glycol, butanediol, and propylene glycol, wherein the second component is a fiber surface. It is a composite fiber that is composite-spun so as to be exposed to 20% or more of the above, and that the single fiber dry heat shrinkage measured according to JIS-L-1015 satisfies the following physical property values (1) and (2) Features.

[Single fiber dry heat shrinkage]
(1) Single fiber dry heat shrinkage at a temperature of 80 ° C., a time of 15 minutes, and an initial load of 0.018 mN / dtex (2 mg / d) is less than 2%.
(2) Single fiber dry heat shrinkage at a temperature of 120 ° C. for 15 minutes at an initial load of 0.018 mN / dtex (2 mg / d) is 3% or less.

  The nonwoven fabric of the present invention contains at least 30% by mass of the polylactic acid-based composite fiber, the second component of the polylactic acid-based composite fiber is melted, and the constituent fibers are thermally bonded to each other. To do.

  The cushion material of the present invention includes the above-mentioned nonwoven fabric.

  The present invention uses a polylactic acid-based composite fiber having a small thermal shrinkage, excellent initial bulk, excellent bulk recovery, flexibility and elasticity compared to a composite fiber using conventional polylactic acid, and the same. Nonwoven fabric and cushioning material can be provided. Specifically, the following effects can be obtained.

(1) A bulky and flexible nonwoven fabric is obtained.
(2) Excellent bulk recovery and excellent cushioning properties.
(3) Especially when the melting point of poly L-lactic acid is 175 ° C. or higher, the thermal processing temperature range in which the bulk can be maintained is wide.
(4) When staple fibers are used, card passing properties are excellent.
(5) In particular, by using at least one kind of crimp selected from corrugated crimps and spiral crimps, the initial bulk is excellent and the bulk recoverability is also excellent.
(6) When the wet nonwoven fabric is used, the core component polylactic acid is a hard resin and the sheath component aliphatic polyester is a flexible resin, so that a flexible paper can be obtained while having a waist. The surface feel is also soft.
(7) Since a nonwoven fabric that is particularly bulky and excellent in bulk elasticity can be obtained, it is suitable for a cushion material.

  The polylactic acid-based composite fiber of the present invention includes poly L-lactic acid having a melting point of 165 ° C. or more as a first component (core component), and succinic acid having a melting point of 100 to 130 ° C. as a second component (sheath component). The aliphatic polyester includes a repeating unit composed of at least one aliphatic dicarboxylic acid component selected from adipic acid and oxalic acid and at least one glycol component selected from ethylene glycol, butanediol, and propylene glycol. By using this combination, it is possible to obtain a bulky nonwoven fabric having a small heat shrinkage rate.

  By using poly-L-lactic acid having a melting point of 165 ° C. or higher as the first component (core component), it is possible to obtain a bulky nonwoven fabric because it has high heat resistance and is difficult to soften during thermal processing. Furthermore, a nonwoven fabric with good bulk recovery can be obtained.

  When heat-adhesive conjugate fibers of polylactic acid are used, it is necessary to lower the melting point of the polylactic acid in the sheath component. However, if the copolymer is used to lower the melting point or the optical purity is lowered, the heat shrinkage rate There was a problem that would become larger. Therefore, the present inventors paid attention to the resin used for the second component (sheath component), knew that the heat shrinkage rate can be reduced by using the aliphatic polyester, and led to the present invention. . The reason for this is that the aliphatic polyester has good compatibility with poly L-lactic acid and does not easily cause core-sheath peeling, has high thermal adhesiveness and high binder properties, or has low heat shrinkability of the resin itself. Presumed. Further, as an advantage of the present invention, since the aliphatic polyester is a relatively soft resin similar to low density polyethylene (LDPE), a soft tactile nonwoven fabric can be obtained. Furthermore, the flexibility of the aliphatic polyester increases the degree of freedom of the thermal bonding point and increases the degree of freedom of deformation of the bonding point. Therefore, in combination with the core component poly L-lactic acid, the bulk recovery property, particularly the initial bulk A nonwoven fabric excellent in recoverability can be obtained. Among these, polybutylene succinate obtained by condensation polymerization of butanediol and succinic acid is most preferable. This is because the melting point is relatively high among the aliphatic polyesters and has high heat resistance.

  In the present invention, the poly L-lactic acid has a melting point of 165 ° C. or higher. The melting point of preferable poly L-lactic acid is 170 or more. Most preferably, it is 175 degreeC or more. When the melting point is less than 165 ° C., the difference in melting point from the sheath component becomes small. As a result, since the difference from the thermal processing temperature becomes small, there is a tendency that the thermal processing is likely to be lost. The upper limit of the melting point of poly L-lactic acid is preferably less than 180 ° C. The melting point of poly-L-lactic acid here is the melting point of virgin resin, and if necessary, other components may be added to increase or decrease the melting point as long as the effects of the present invention are not impaired. Can be made.

  The poly-L-lactic acid may be used alone, but if a nucleating agent is added to increase the melting point and the crystallization temperature, the heat resistance is further improved, and a bulky nonwoven fabric with good bulk recoverability is obtained. Therefore, it is preferable. Any known nucleating agent may be used, but inorganic fillers such as calcium carbonate, talc, silica, and aluminum compounds, phosphate ester metal salts, and amide compounds are preferable. The nucleating agent is preferably contained in an amount of 0.5 to 3% by mass with respect to poly L-lactic acid. For example, when 2% by mass of talc and an amide compound are added, the melting point of poly L-lactic acid increases by about 7 ° C.

  The optical purity of poly L-lactic acid is preferably 95% or more, more preferably 99% or more, and most preferably 99.5% or more. When the optical purity is less than 95%, the softening point tends to be low, and it tends to be sag during heat processing, and the bulk recovery property tends to be poor.

  Since the poly L-lactic acid used in the present invention tends to have high heat resistance and large flexural elasticity, it is easy to obtain a non-woven fabric that has a small thermal shrinkage, a large bulk, and excellent bulk recoverability as in the present invention. .

  An example of a polymer having a melting point of poly L-lactic acid of 175 ° C. or higher and an optical purity of 99.5% or higher is a trade name “U′z S-99” (manufactured by Toyota Motor Corporation).

  In addition to the poly-L-lactic acid, other resins may be mixed with the first component as long as the effects of the present invention are not impaired. Examples of the other resin include aromatic polyesters such as polyethylene terephthalate, polybutylene terephthalate, and polytrimethylene terephthalate, aromatic aliphatic polyesters, aliphatic polyesters, and polyolefins. The proportion of poly L-lactic acid in the first component is preferably 70% by mass or more, and more preferably 90% by mass or more.

  Examples of the aliphatic polyester include polybutylene succinate, polybutylene adipate, polybutylene sebacate, polyethylene oxalate, polyethylene succinate, polyethylene adipate, polyethylene azelate, polyhexamethylene sebacate, polyneopentyl oxalate, and these The copolymer of these is mentioned. Among them, polybutylene succinate, which is a condensate of succinic acid and 1,4-butanediol, has a relatively high melting point of about 110 ° C., is excellent in fiber productivity, nonwoven fabric processability, and nonwoven fabric physical properties, and is a future biomass. It is the most promising resin as a resin that can be used as a raw material and is preferable.

  A preferable range of the melting point of the aliphatic polyester is 100 ° C. or higher and 130 ° C. or lower. A more preferable melting point range is 110 ° C. or more and 125 ° C. or less. When the melting point is less than 100 ° C., the melted resin discharged from the nozzle during melt spinning is slow to solidify, and a fused yarn tends to be generated. On the other hand, when the melting point exceeds 130 ° C., the difference in melting point from the core component becomes small, and as a result, the difference from the thermal processing temperature becomes small, so that the bulk tends to be reduced during the thermal processing.

  In addition to the aliphatic polyester, other resins may be mixed with the second component as long as the effects of the present invention are not impaired. Examples of the other resin include polylactic acid, polyhydroxybutyrate, polyhydroxybutyrate valerate, polycaprolactam, aromatic polyester, polyamide, and polyolefin. The proportion of the aliphatic polyester in the second component is preferably 70% by mass or more, and more preferably 90% by mass or more.

If the fiber cross-sectional form is a concentric circle, the strength of the nonwoven fabric is preferably increased. An eccentric structure is more preferable because the initial bulk and bulk recovery can be further increased. Eccentricity refers to a state in which the first component poly-L-lactic acid is displaced from the center of gravity of the fiber, and specifically includes an eccentric core-sheath type or a parallel type. As shown in FIG. 1, the eccentricity is obtained by magnifying and photographing a fiber cross section of a composite fiber with a microscope or the like, and the center of gravity (3) of the core component (1) is C1, and the center of gravity (4) ) Is Cf, and the radius (5) of the composite fiber (10) is rf, it is a numerical value represented by the following formula.
[Eccentricity (%) = (Cf−C1) × 100 / rf]
The eccentricity is preferably 5% or more and 50% or less. A more preferable eccentricity is 7% or more and 30% or less.

  As the fiber cross section (hereinafter, generally referred to as an eccentric cross section) in which the gravity center position (3) of the first component (1) is deviated from the fiber gravity center position (4), the eccentric core-sheath type shown in FIG. It is a preferable form. Depending on the case, even a multi-core type may be used in which multi-core portions are gathered and are shifted from the center of gravity of the fiber. In particular, the eccentric core-sheath fiber cross section is preferable in that desired wave shape crimps and / or spiral crimps can be easily expressed. The eccentricity ratio of the eccentric core-sheath composite fiber is preferably 5 to 50%. A more preferable eccentricity is 7 to 30%. Moreover, the form in the fiber cross section of the first component may be an elliptical shape, Y shape, X shape, well shape, polygonal shape, star shape, or the like in addition to the circular shape. Other than the circular shape, an elliptical shape, a Y shape, an X shape, a well shape, a polygonal shape, a star shape, or a hollow shape may be used.

  When the composite ratio becomes rich in the sheath, the strength of the nonwoven fabric increases, but the resulting nonwoven fabric tends to be hard and the bulk recovery tends to be poor. On the other hand, if the core becomes too rich, the number of adhesion points becomes too small, the strength of the nonwoven fabric tends to be small, and the bulk recovery property tends to be poor. Accordingly, the composite ratio (core / sheath) is preferably 8/2 to 4/6, more preferably 7/3 to 45/55, and most preferably 6/4 to 5/5.

  When making the composite fiber which has the said eccentric type cross section into a bulky nonwoven fabric, it is good to use a hot-air processed nonwoven fabric after crimping a fiber and making it into a card | curd or an air web. A preferable number of crimps is 5 pieces / 25 mm or more and 24 pieces / 25 mm or less. A more preferable number of crimps is 10 pieces / 25 mm or more and 20 pieces / 25 mm or less. If the number of crimps is less than 5 pieces / 25 mm, the number of crimps is too small, making it difficult to form a web or obtaining a bulky nonwoven fabric. On the other hand, when the number of crimps exceeds 24/25 mm, the number of crimps is too large, the defibration property is deteriorated, and it becomes difficult to obtain a card web or air array web having a good texture. Moreover, there exists a tendency for the bulk of a nonwoven fabric to become small or for a bulk recovery property to also become small.

  The composite fiber having an eccentric cross section has a number of crimps of 5/25 mm or more and 24/25 mm or less when heat-treated at a temperature 5 ° C. higher than the melting point of the second component. A more preferable number of crimps is 10 pieces / 25 mm or more and 20 pieces / 25 mm or less. If the number of crimps after heat treatment is less than 5 pieces / 25 mm, the bulk tends to be small, and the bulk recoverability tends to be small. On the other hand, when the number of crimps after the heat treatment exceeds 24 pieces / 25 mm, the resulting nonwoven fabric tends to deteriorate.

  Furthermore, the composite fiber having the eccentric cross section has an increase in the number of crimps before and after the heat treatment is 5 pieces / 25 mm or less. A more preferable increase in the number of crimps is 3 pieces / 25 mm or less. The most preferable increase in the number of crimps is 2 pieces / 25 mm or less. If the increase in the number of crimps before and after heat treatment exceeds 5 pieces / 25 mm, the web area shrinkage rate during heat treatment tends to increase, and the formation tends to deteriorate. Further, the bulk tends to be small and the bulk recovery property tends to be small.

  The conjugate fiber of the present invention preferably has a crimp rate of 5% or more and 30% or less. A more preferable crimp rate is 10% or more and 25% or less. If the crimp rate is less than 5%, the fibers become straight and it is difficult to obtain a bulky nonwoven fabric. When the crimp rate exceeds 30%, the defibration property is deteriorated, and it becomes difficult to obtain a card and an air lay web having a good texture.

  FIG. 2 shows a crimped form of the composite fiber in one embodiment of the present invention. The corrugated crimp referred to in the present invention refers to a curved crest as shown in FIG. 2A. Spiral crimp refers to a crimped crest as shown in FIG. 2B. A crimp in which a wave shape crimp and a spiral crimp as shown in FIG. 2C are mixed is also included in the present invention. In the case of ordinary mechanical crimping as shown in FIG. 3, it is difficult to sufficiently increase the initial volume when a nonwoven fabric is formed if the crimped crest has an acute angle, that is, a so-called serrated crimp. . Further, it is inferior in surface elasticity against compression, so-called spring effect, and it is difficult to obtain particularly sufficient initial bulk recovery. The present invention also includes a crimp in which the sharp crimp of the mechanical crimp as shown in FIG. 4 and the corrugated crimp shown in FIG. 2A are mixed.

  As described above, the crimped shape is preferably at least one kind of crimp selected from mechanical crimps, corrugated crimps, and spiral crimps. In order to obtain a non-woven fabric that is more bulky and excellent in bulk recoverability, corrugated crimps in which the crests are curved and spiral crimps are preferred. This is because by using such a crimped shape, the spring effect in the case of a non-woven fabric is exhibited.

  In the stretching method, in order to obtain mechanical crimping, it is preferable that stretching is performed at a temperature below the glass transition point of polylactic acid, and then tension heat setting is performed at a temperature lower than the melting point of the second component (sheath component). The reason for carrying out the stretching temperature below the glass transition point of polylactic acid (usually 55-60 ° C.) is that the stretching ratio can be increased. The reason for setting the tension heat at a temperature lower than the melting point of the second component (sheath component) is to crystallize polylactic acid to impart heat shrinkage resistance, bulkiness and bulk recovery. Specifically, it is stretched 2 to 4 times at a temperature not lower than 20 ° C. below the glass transition point of polylactic acid and not higher than 5 ° C. below the glass transition point, and not lower than a temperature lower than the melting point of the second component by 30 ° C. It is preferable to perform tension heat setting at a temperature not higher than 5 ° C. below the melting point of the two components.

  In the case of corrugated or helical crimps, the fiber cross section is an eccentric cross section, and stretched at a temperature not lower than the glass transition point of polylactic acid and lower than the melting point of the second component (sheath component). Is preferably not implemented. This is because a mechanical crimp is likely to occur when the tension heat set is performed. The reason why the polylactic acid is stretched at a temperature equal to or higher than the glass transition temperature of the polylactic acid is to cause crystallization of the polylactic acid simultaneously with the stretching. Specifically, it is preferably stretched 2 to 4 times at a temperature not lower than 5 ° C. above the glass transition point, not higher than the melting point of the second component (sheath component) and not higher than 40 ° C. higher than the glass transition point.

  In this case, the stretching is more preferably performed in warm water. This is because, when the hot water is used, the core component and the sheath component are more likely to be distorted, and the crimped mountain is easily bent.

  Since the core component poly-L-lactic acid and the sheath component aliphatic polyester are highly compatible, it is difficult to cause the core-sheath peeling, and a high-strength heat-bonded nonwoven fabric can be obtained. Furthermore, since the sheath component is excellent in adhesion to polylactic acid, polyesters other than poly L-lactic acid, and cellulose, a nonwoven fabric having a stronger adhesion point can be obtained.

  In the polylactic acid-based composite fiber of the present invention, the single fiber dry heat shrinkage measured according to JIS-L-1015 satisfies the following physical property values (1) and (2).

[Single fiber dry heat shrinkage]
(1) Single fiber dry heat shrinkage at a temperature of 80 ° C., a time of 15 minutes, and an initial load of 0.018 mN / dtex (2 mg / d) is less than 2%.
(2) Single fiber dry heat shrinkage at a temperature of 120 ° C. for 15 minutes at an initial load of 0.018 mN / dtex (2 mg / d) is 3% or less.

  The single fiber dry heat shrinkage (1) at a temperature of 80 ° C. is preferably 1.5% or less. The reason why the temperature is defined as 80 ° C. is that it is a measure of the shrinkability of the single fiber when heat-treated at a temperature at which the second component does not melt. This is because, by satisfying the above range, the fiber structure to be obtained can be effectively used in applications where the composite fiber does not require the thermal adhesiveness. When the single fiber dry heat shrinkage ratio (1) is 2% or more, the shrinkage of the single fiber and the web during heat treatment becomes excessively large, the texture of the web is disturbed, the bulk is reduced, and the bulk recoverability is also small. Because there is a tendency to become.

  The single fiber dry heat shrinkage (2) at a temperature of 120 ° C. is preferably 2.5% or less. The reason why the temperature is set to 120 ° C. is that it is a measure of the contractility of the fiber when heat-treated at a temperature at which the second component melts or softens, particularly when heat-bonded. When the single fiber dry heat shrinkage rate (2) exceeds 3%, the shrinkage of the fiber and the web during heat treatment tends to be too large, and the texture of the web is disturbed, the bulk becomes small, and the bulk recoverability tends to be small. Because there is.

  The single fiber strength of the polylactic acid-based composite fiber of the present invention is not particularly limited, but if it is too large, orientation crystallization tends to be large and biodegradability tends to be poor, so that it is 1 cN / dtex or more and 3 cN / dtex or less. The range is preferably 1 cN / dtex or more and 2 cN / dtex or less. If it is less than 1 cN / dtex, fiber tearing easily occurs in the card process.

  A preferable fineness is 1 dtex or more and 30 dtex or less. A more preferable fineness is 2 dtex or more and 20 dtex or less. In particular, when the crimped shape is corrugated or spiral, and the nonwoven fabric is excellent in bulk recovery, the most preferable fineness is 3 dtex or more and 15 dtex or less, which is particularly convenient when used for a cushion material.

  The polylactic acid-based composite fiber of the present invention can be used for fiber structures such as yarns, nonwoven fabrics, and woven / knitted fabrics. In particular, when used as a nonwoven fabric, it contains at least 30% by mass of the polylactic acid-based composite fiber of the present invention, the second component of the polylactic acid-based composite fiber is melted, and the constituent fibers are thermally bonded. Is preferred.

  Examples of the fiber web form constituting the nonwoven fabric of the present invention include a parallel web, a semi-random web, a random web, a cross lay web, a Chris cross web, an air lay web, and a wet papermaking web. The fiber web is effective when the second component is bonded by heat treatment. The fiber web may be subjected to needle punching or hydroentanglement as necessary. The means for the heat treatment is not particularly limited, but if the function of the composite fiber of the present invention is sufficiently exhibited, the pressure of the wind pressure such as a hot air through heat treatment machine, a hot air up-and-down heat treatment machine, an infrared heat treatment machine, etc. It is preferable to use a heat treatment machine that does not take much.

  The nonwoven fabric of the present invention has a bulk recovery rate immediately after dewetting (hereinafter referred to as initial bulk recovery rate) obtained by the following measurement at an atmospheric temperature of 25 ° C. of 55% or more and a bulk recovery rate after 24 hours of dewetting ( Hereinafter, the long-term bulk recovery rate) preferably satisfies 80% or more. Such a nonwoven fabric can be obtained by including at least 30% by mass of the composite fiber having the eccentric cross section.

[Bulk recovery rate]
A necessary number of nonwoven fabrics cut into 10 cm square are prepared and superposed so that the total basis weight is about 1000 g / m ^2, and the initial total thickness (To) is measured. A 10 cm square weight of 9.8 kPa load is placed on the laminated nonwoven fabric, a load is applied for 24 hours in an atmosphere at 25 ° C., the load is removed after 24 hours, and the total thickness (T ₁ ), and the total thickness (T ₂ ) after 24 hours of dewetting, the bulk recovery rate of the nonwoven fabric is calculated by the following formula, and the initial bulk recovery rate and the long-term bulk recovery rate are obtained respectively.

Initial bulk recovery rate (%) = (T ₁ / T ₀ ) × 100
Long-term bulk recovery rate (%) = (T ₂ / T ₀ ) × 100
As for the nonwoven fabric of this invention, it is more preferable that an initial stage bulk recovery rate is 60% or more. The long-term bulk recovery rate is more preferably 85% or more. When the initial bulk recovery rate and / or long-term bulk recovery rate satisfies the above range, the cushion material can be excellent.

  The cushion material of the present invention uses the nonwoven fabric as at least a part. The cushion material as used in the present invention refers to interior materials such as household chairs and vehicle seats, sanitary materials such as diapers and sanitary napkins, cosmetic materials such as filters and cosmetic puffs, molded articles such as brass pads, etc. , Refers to the ones that are mainly used urethane foam. Since the cushion material of the present invention is excellent in initial bulk and bulk recoverability, it is suitable as a substitute material for urethane foam.

  Hereinafter, the present invention will be described more specifically with reference to Examples and Comparative Examples.

(Examples 1-4, Comparative Examples 1-3)
Specific conditions are shown in Tables 1-2. Other conditions will be described below.
(1) Resin (i) Poly L-lactic acid A. U'z S-99 manufactured by Toyota Motor Corporation Melting point (mp): 176 ° C, optical purity: 99.6%, glass transition temperature (Tg): 57 ° C, melt index according to JIS-K-7210 (MI; measurement temperature) 190 ° C., load 2.16 kgf (21.18 N)): 7.2 g / 10 min. Lacia H-100J manufactured by Mitsui Chemicals, Inc. mp: 170 ° C., Tg: 55 ° C., MI: 8 g / 10 minutes (ii) Aliphatic polyester C.I. Bionore # 1020 (polybutylene succinate) manufactured by Showa Polymer Co., Ltd. mp: 112 ° C. MI: 20 g / 10 min. GS-Pla AZ71T (polybutylene succinate) manufactured by Mitsubishi Chemical Corporation mp: 112 ° C. MI: 20 g / 10 min. Bionore # 3020 (polybutylene succinate adipate) mp: 95 ° C. MI: 20 g / 10 min (iii) Aromatic aliphatic polyester It has a repeating unit consisting of terephthalic acid, sulfonic acid metal salt, aliphatic dicarboxylic acid, ethylene glycol and diethylene glycol, and in the acid component, terephthalic acid is about 50 mol% to about 90 mol%, and sulfonic acid metal salt is about 0.2 Mol% to about 6 mol%, and aliphatic dicarboxylic acid is about 4 mol% to about 49.8 mol%, and in the glycol component, ethylene glycol is about 50 mol% to about 99.9 mol% and diethylene glycol is about Aromatic aliphatic polyester copolymer of 0.1 mol% to about 50 mol% mp: 200 ° C, Tg: 45 ° C
(2) Polymer of core and sheath Example 1, 4: Core A / sheath C Fiber melting point 173.8 ° C / 112.9 ° C
Example 2: Core A / Sheath D
Example 3: Core B / Sheath C Fiber melting point 163.1 ° C / 113.3 ° C
Comparative Example 1: Core A / Sheath E
Comparative Examples 2 and 3: Core F / Sheath C
(3) Extrusion temperature Core resin (poly L-lactic acid) 240 ° C
Sheath resin (polybutylene succinate) 210 ° C
Nozzle base temperature: 240 ° C
(4) Take-up speed: 410 m / min (5) Section: concentric circle, eccentricity (6) Compound ratio: 5/5 (mass ratio)
(7) Unstretched fineness: 9 dtex
(8) Stretching temperature: Wet (warm water) 50 ° C one step + 80 ° C tension heat set, B. Wet (warm water) 80 ° C one step (9) Stretch ratio: 2.7 times (10) Drying temperature: 90 ° C
(11) Product fineness x Cut length: 4.4 dtex x 51 mm
[Evaluation methods]
(1) Melting point: Using a differential scanning calorimeter (manufactured by Seiko Instruments Inc.), setting the polymer sample amount to 5.0 mg, holding at 220 ° C. for 5 minutes, and then decreasing the temperature to 40 ° C. at a rate of 10 ° C./min. After cooling, the mixture was melted at a temperature increase rate of 10 ° C./min to obtain heat of fusion curves for each of the first and second components, and the melting point was determined from the obtained heat of fusion curves.
(2) Glass transition temperature: After raising the temperature to 220 ° C. and holding for 10 minutes, the temperature is lowered from 220 ° C. to −20 ° C. at a rate of temperature drop of 10 ° C./min and held for 10 minutes, and then from −20 ° C. to 220 ° C. The glass transition point when the temperature was raised at a rate of temperature rise of 10 ° C./min was defined as the glass transition temperature.
(3) Fiber melting point: Using a differential scanning calorimeter (manufactured by Seiko Instruments Inc.), the fiber sample amount was 6.0 mg, and the temperature was raised from normal temperature to 200 ° C. at a temperature increase rate of 10 ° C./min. The fibers were melted, and the fiber melting points of the first component and the second component were determined from the obtained heat of fusion curve.
(4) Single fiber strength: According to JIS L 1015, the load value at the time of fiber cutting was measured using a tensile tester when the holding distance of the sample was 20 mm.
(5) Number of crimps and crimp rate: Measured according to JIS L 1015.
(6) Number of crimps after heat treatment: A single fiber sample after measuring the number of crimps was taken out, suspended vertically in an oven adjusted to a temperature of the melting point of the second component + 5 ° C., and heated for 1 minute. Next, the number of crimps of the heated single fiber was measured according to JIS L 1015, and the number of crimps after heat treatment was determined. And the difference of the number of crimps before and behind heat processing was calculated | required.
(7) Thickness: Using a thickness tester manufactured by Mitutoyo Corporation, ID-C1012C, the thickness after 5 seconds was obtained under the condition of an applied load of 2.94 cN / cm ² .
(8) Web shrinkage ratio: The card web before thermal processing was cut into length: 100 mm and width: 100 mm, and the area reduction rate was measured when the card web was thermally processed at a predetermined temperature.

  The above results are shown in Tables 1-2.

  The polylactic acid-based composite fibers of Examples 1 to 4 were small in heat shrinkage and could obtain a nonwoven fabric excellent in initial bulk. In particular, the polylactic acid-based composite fiber having an eccentric cross section of Example 4 was excellent in initial and long-term bulk recovery properties, and a flexible and elastic nonwoven fabric could be obtained. On the other hand, in Comparative Example 1, because the melting point of the aliphatic polyester as the sheath component was low, fusion yarns were generated during spinning, and the spinning performance was poor and the take-off was stopped. Since the comparative example 2 used aromatic aliphatic polyester for the core component, the specific volume became low.

  When Example 4 was compared with Comparative Example 3, the nonwoven fabric of Example 4 had an initial thickness of 52 mm, an initial bulk recovery rate at 25 ° C. of 65%, and a long-term bulk recovery rate of 87%. On the other hand, the nonwoven fabric of Comparative Example 3 had an initial thickness of 47 mm, an initial bulk recovery rate at 25 ° C. of 52%, and a long-term bulk recovery rate of 87%. Example 4 was found to be superior in initial thickness and bulk recoverability compared to Comparative Example 3.

  As a reference example, a biodegradable composite short fiber of polylactic acid (trade name Terramac PL80, manufactured by Unitika Co., Ltd.) having a melting point of the core component of 170 ° C. and a melting point of the sheath component of 130 ° C. was prepared. The reference example was a non-woven fabric having a remarkably large heat shrinkage rate and a remarkably low specific volume as compared with Examples 1 to 4.

  Further, in the polylactic acid-based composite fiber having the eccentric cross section of Example 4, the number of crimps when heated to the melting point of the second component + 5 ° C. was an increase of 1.9 crests / 25 mm compared to before the heat treatment. It was. Unlike conventional latently crimped composite fibers, corrugated crimps became apparent, so that when the fibers and nonwoven fabrics were made, there was little heat shrinkage and a bulky nonwoven fabric was obtained.

  From the above results, the present invention has a low thermal shrinkage, excellent initial bulk, excellent bulk recovery, soft and elastic polylactic acid-based composite fibers, compared to conventional composite fibers using polylactic acid, and It could be a non-woven fabric. Moreover, the said composite fiber and a nonwoven fabric can be used conveniently as a cushioning material.

  The polylactic acid-based composite fiber of the present invention has low thermal shrinkage and is bulky, and particularly in the case of a composite fiber having a fiber cross section in which the position of the center of gravity of the second component is shifted from the position of the center of gravity of the fiber, Can be used for sanitary materials such as diapers and napkin members, filters, wipers, agricultural materials, food packaging materials, garbage bags, automotive materials and the like. In particular, the cushion material is suitable mainly as a substitute material for urethane foam, such as chairs, sanitary materials, filters, cosmetic puffs, cups such as brassiere, and the like.

FIG. 1 shows a fiber cross section of a composite fiber according to an embodiment of the present invention. 2A to 2C show crimped forms of the composite fiber in one embodiment of the present invention. FIG. 3 shows a form of mechanical crimp (sawtooth crimp). FIG. 4 shows a crimped form of a composite fiber according to another embodiment of the present invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 1st component 2 2nd component 3 The gravity center position 4 of a 1st component The gravity center position 5 of a composite fiber Radius 10 of a composite fiber Composite fiber

Claims (7)

A first component comprising poly L-lactic acid having a melting point of 165 ° C. or higher;
Repeat consisting of at least one aliphatic dicarboxylic acid component selected from succinic acid, adipic acid and oxalic acid having a melting point of 100 to 130 ° C. and at least one glycol component selected from ethylene glycol, butanediol and propylene glycol A second component comprising an aliphatic polyester comprising units,
A composite fiber which is composite-spun so that the second component is exposed to 20% or more of the fiber surface;
A polylactic acid-based composite fiber characterized in that the single fiber dry heat shrinkage measured according to JIS-L-1015 satisfies the following physical property values (1) and (2).
[Single fiber dry heat shrinkage]
(1) Single fiber dry heat shrinkage at a temperature of 80 ° C., a time of 15 minutes, and an initial load of 0.018 mN / dtex (2 mg / d) is less than 2%.
(2) Single fiber dry heat shrinkage at a temperature of 120 ° C. for 15 minutes at an initial load of 0.018 mN / dtex (2 mg / d) is 3% or less.   The polylactic acid-based composite fiber according to claim 1, wherein the fiber melting point of poly-L-lactic acid when it is made into a composite fiber is 165 ° C or higher.   The composite fiber has a fiber cross section in which the second component occupies at least 20% of the fiber surface, the center of gravity of the second component deviates from the center of gravity of the fiber, and is corrugated in the fiber length direction. 2. The polylactic acid-based composite fiber according to claim 1, wherein the polylactic acid-based composite fiber has at least one kind of crimp selected from crimps and spiral crimps, and the number of crimps is 5/25 mm or more and 24/25 mm or less.   The composite fiber has a number of crimps of 5/25 mm or more and 24/25 mm or less when heat-treated at a temperature 5 ° C. higher than the melting point of the aliphatic polyester, and the increase in the number of crimps before and after the heat treatment is 5 The polylactic acid-based composite fiber according to claim 3, wherein the number is 25 pieces or less per piece.   A non-woven fabric containing at least 30% by mass of the polylactic acid-based composite fiber according to any one of claims 1 to 4, wherein the second component of the polylactic acid-based composite fiber is melted and the constituent fibers are thermally bonded to each other . A non-woven fabric containing at least 30% by mass of the polylactic acid-based composite fiber according to claim 3 or 4, wherein the bulk recovery rate (hereinafter referred to as initial bulk recovery) immediately after dewetting obtained by the following measurement at an atmospheric temperature of 25 ° C. Rate) is 55% or more and the bulk recovery rate after 24 hours of dewetting (hereinafter referred to as long-term bulk recovery rate) is 80% or more.
[Bulk recovery rate]
A necessary number of nonwoven fabrics cut into 10 cm square are prepared and superposed so that the total basis weight is about 1000 g / m ^2, and the initial total thickness (To) is measured. A 10 cm square weight of 9.8 kPa load is placed on the laminated nonwoven fabric, a load is applied for 24 hours in an atmosphere at 25 ° C., the load is removed after 24 hours, and the total thickness (T ₁ ), and the total thickness (T ₂ ) after 24 hours of dewetting, the bulk recovery rate of the nonwoven fabric is calculated by the following formula, and the initial bulk recovery rate and the long-term bulk recovery rate are obtained respectively.
Initial bulk recovery rate (%) = (T ₁ / T ₀ ) × 100
Long-term bulk recovery rate (%) = (T ₂ / T ₀ ) × 100   The cushion material containing the nonwoven fabric of Claim 5 or 6.

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