JP2005139566A - Spun lace comprising polylactic acid fiber and pulp - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a spun lace which has a uniform weave, is flexible, has a practical strength even with a relative low added specific energy, can biologically be degraded with microorganisms after used, and can widely be used as a substrate for medical/sanitary articles and as a substrate for other industrial articles/household articles. <P>SOLUTION: This spun lace having a geometric average breaking length value of ≥2 km in the longitudinal and latitudinal directions is obtained by subjecting a web having a fiber length of 7 to 20 mm and an aspect ratio of ≤1200 and prepared from polylactic acid fibers and pulp by a wet paper-making method to a water interlacing method. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a spunlace obtained by producing a web composed of polylactic acid fibers and pulp using a wet papermaking method, and hydroentangled with the web. More specifically, the texture is uniform and flexible, and The present invention relates to a spunlace that retains strength suitable for practical use and can be biodegradable by microorganisms after use.

  Nonwoven fabric obtained by hydroentanglement has the characteristics of soft touch, no binder, hygienic and practical strength, and is widely used as a base material for medical and hygiene products and other industrial and household products. It is used. As a nonwoven fabric made of short fibers, there is a so-called dry method in which web production is performed in a dry manner, and since it has an appropriate strength with flexibility, for example, a nonwoven fabric hydroentangled with a two-layer sheet of a pulp sheet and a polyester fiber web is used as a medical It is used as a base material for cleaning and a base material for wiping. Here, the pulp is used for performance as clogging with fine fibers (thus providing liquid barrier property and bacterial barrier property), and for imparting high liquid absorbency and high liquid retention to the nonwoven fabric. However, the dry method generally has a disadvantage that the fibers are not uniformly distributed, that is, the texture is not good because the web is formed by a card method or the like using relatively long fibers. In order to improve this, various methods of hydroentanglement after using a so-called wet method in which a web is formed by a wet papermaking method have been reported.

On the other hand, as materials used for these non-woven fabrics, synthetic fibers such as polyester, polyolefin and polyamide, or materials such as these fibers and pulp fibers have been used. Since these synthetic fibers are difficult to be decomposed when left in the natural world after use, they need to be incinerated for volume reduction. However, if the fibers made from these fossil resources are incinerated, carbon dioxide will be released into the atmosphere, which will promote global warming.
On the other hand, it has biodegradability and does not increase the amount of carbon dioxide in the atmosphere even if it generates carbon dioxide by incineration. It is mainly made of rayon fiber as a fiber made from plants, and a web is produced by a wet method. However, there has been a report that hydroentangled nonwoven fabric has been reported, but there is a problem that the use is limited because sufficient strength cannot be obtained.

In recent years, the development of biodegradable thermoplastic resins that biodegrade with microorganisms has progressed. Furthermore, the global warming issue has been highlighted, and the concept of “carbon neutral” that does not increase carbon dioxide in the atmosphere has been regarded as important. One of the biodegradable thermoplastic resins that meet this concept is polylactic acid. Since the resin has a relatively high melting point and high strength, a nonwoven fabric (Patent Document 1) in which water is entangled with a short fiber web has been studied.
However, these nonwoven fabrics have a disadvantage that the web is manufactured by a dry method or is partially thermocompression bonded, and is excellent in strength, but has a poor texture.
Therefore, a hydrogenation entanglement method (Patent Document 2) that gives a temperature below the melting point of polylactic acid and above the glass transition temperature during hydrogenation entanglement using a web produced by a wet method has been reported, Although it is disclosed that higher entanglement is achieved, not only is the operation complicated, but it is difficult to improve the tensile strength during drying, and entanglement is performed using a lower energy level, which is practical. A nonwoven fabric having a high strength has been desired.
Furthermore, in general, it is necessary to use finer fibers if the fiber length is shortened in consideration of papermaking property and aspect ratio in order to facilitate hydroentanglement of the web created by the wet papermaking method. There was also.
JP-A-7-126970, JP-A-7-133511, JP-A-7-13369, JP-A-2000-24852 Special table 2003-508640 gazette

  It is an object of the present invention to provide a spunlace that has a good texture, is flexible, has a practical strength with a relatively low added specific energy, and is biodegraded by microorganisms after use.

  As a result of intensive studies to solve the above problems, the present inventors have found that the problems can be solved by using specific polylactic acid fibers and pulp, and have completed the present invention.

  The first aspect of the present invention is the longitudinal and lateral cracks shown in Equation 3, which are hydroentangled with a web obtained by a wet papermaking method comprising a polylactic acid fiber having a fiber length of 7 to 20 mm and an aspect ratio of 1200 or less and pulp. This is a span lace in which the geometric average of the longitudinal length is 2 km or more.

The second aspect of the present invention is the above-described spunlace in which the additional specific energy of hydroentanglement expressed by Equation 4 is 0.1 to 0.3 kwh / kg.

  In the present invention, polylactic acid fibers having a specific fiber length and aspect ratio, or a mixture thereof with a pulp, are wet-made, so that the texture is uniform and the practical strength is obtained by hydroentanglement with a relatively low added specific energy. Further, after use, it has the effect of being biodegradable by microorganisms.

Hereinafter, the present invention will be described in detail.
The polylactic acid fiber used in the present invention is a thermoplastic aliphatic polyester, which is poly (D-lactic acid), poly (L-lactic acid), a copolymer of D-lactic acid and L-lactic acid, D-lactic acid. And a hydroxycarboxylic acid copolymer, a copolymer of L-lactic acid and hydroxycarboxylic acid, a copolymer of DL-lactic acid and hydroxycarboxylic acid, etc., and has a number average molecular weight of 20,000 or more, preferably It is obtained by spinning 40,000 or more polymers by the melt spinning method and drawing.
In the present invention, a fiber cut to a specific fiber length and aspect ratio after stretching is used.

  In the present invention, the polylactic acid fiber used has a fiber length of 7 to 20 mm, preferably 8 to 15 mm, and an aspect ratio of 1200 or less. If the fiber length exceeds 20 mm or the aspect ratio exceeds 1200, it becomes difficult to disperse, and if it is treated for a long time to improve the dispersion or if it is dispersed strongly, it will cause twisting, both dispersibility and avoidance It becomes difficult to satisfy. On the other hand, when the fiber length is less than 7 mm, it is difficult to obtain strength by hydroentanglement.

  As pulp used in the present invention, unbleached pulp or bleached pulp obtained by digesting coniferous or hardwood wood by kraft method, sulfite method, soda method, etc., or mechanical pulp such as ground pulp, thermomechanical pulp, hemp, etc. Non-wood pulp and the like. Among these pulps, those having a long fiber length are more preferable in terms of strength. The pulp may be used only by disaggregation or be beaten to some extent.

  In the present invention, the weight ratio between the polylactic acid fiber and the pulp is preferably 8/2 to 2/8. If there is too little pulp, the clogging performance and liquid absorbency will be insufficient. Moreover, when there are too few polylactic acid fibers, intensity | strength will become inadequate.

In the present invention, biodegradable fibers other than polylactic acid can be mixed and used within a range not impairing the physical properties of the present invention.
In the present invention, a biodegradable heat-fusible fiber can also be used as a binder. A core-sheath type composite fiber is used as the heat-sealing fiber. Examples of the core-sheath type composite fiber include a sheath component that has a low melting point by increasing the D-form ratio of the polylactic acid resin and a core component of a regular blend, and a core component of a high melting point biodegradable polyester. What consists of a sheath component of polybutylene succinate of low melting point can be mentioned. This heat-fusible fiber is preferably blended so as not to impair the flexibility of the spunlace, and is usually 30% or less, preferably 20% or less of the total fiber. Further, heat fusion may be performed either before or after hydroentanglement.

The spunlace of the present invention has a geometric average of the longitudinal and lateral tear lengths of 2 km or more. If the geometric average is 2 km or less, the application is limited, and for example, it is difficult to use for medical surgical clothes and sheets that require strength.
Moreover, although the basic weight of a spunlace is selected by a use, it is 20-200 g / m < ² > normally.

The spunlace of the present invention is produced according to a known method of wet-type spunlace.
First, polylactic acid fibers are disaggregated. Disaggregation refers to an operation in which a bundle of fibers is disassembled into a single yarn in water. There are beaters, pulpers, etc. as disaggregation facilities. The fiber concentration at the time of disaggregation needs to be lower as the fiber has a longer fiber length. Generally, it is 3% or less. In order to promote disaggregation, usually a few percent of dispersant per fiber is added. The polylactic acid fiber may be disaggregated alone or mixed with pulp and disaggregated. When mixing and disaggregating with pulp, it is preferable to first disaggregate the pulp and then add polylactic acid fibers to disaggregate.
The resulting slurry is diluted with water to make paper. As the paper machine, an inclined short net paper machine or a circular net paper machine is generally used. When paper is made of polylactic acid fibers or a slurry mainly composed of polylactic acid fibers, about 0.1 to 0.5% of a sticking agent (formation forming aid) is added to the fibers to improve the formation. Furthermore, a very small amount of antifoaming agent is added for the purpose of eliminating foam generated by the dispersant or the sticking agent. It is also possible to prepare a web in which a polylactic acid fiber slurry and a pulp slurry are separately prepared and two layers are laminated.

The web thus produced is placed on a support on-line or off-line and sent to the hydroentanglement process. Nozzles for performing water entangling generally have a diameter of 0.07 to 0.2 mm and a nozzle interval of 0.3 to 1.5 mm. The water pressure is preferably 10 to 150 kg / cm ² .
Entanglement can be done from only one side or from both sides.
The entangled web is dried with a dryer after excess water is removed by suction or pressing.

In the present invention, the additional specific energy of hydroentanglement is 0.1 to 1.0 kwh / kg, preferably 0.1 to 0.3 kwh / kg, and is preferably lower than the energy level of conventional hydroentanglement. One of the features of the present invention is that it can be carried out at such a low level of energy.
If the additional specific energy is too low, sufficient strength cannot be obtained. On the other hand, if it exceeds this, the texture may be disturbed, or the fibers may enter the support and become difficult to peel off, which is not preferable.

Hereinafter, the present invention will be described more specifically with reference to examples.
In addition, the measured value in an Example was measured with the following method.
1) Breaking length: JIS P-8113
2) Flexibility: JIS L-1096A method (45 ° cantilever method)
3) Texture: Visually, three grades were evaluated: ◎: very good, ○: good, △: slightly bad.

Example 1
NBKP (hinton) is disaggregated with a tappi disintegrator, and then the dispersant is 3% polylactic acid fiber, 1.3 dtex x 12 mm polylactic acid fiber (aspect ratio: 1000) (Lactron made by Kanebo Synthetic Fiber) and pulp, : Pulp = 7: 3 (weight ratio) was added and disaggregated. The fiber concentration was 1%. It was poured diluted 5-fold Nebazai (PEO) 0.3% to to fiber, to give the handsheets having a basis weight of 70 g / ^{m 2.} This was placed on a support, and water entangled three times at a pressure of 60 kg / cm ² with a nozzle having a nozzle diameter of 0.1 mm and a nozzle interval of 1 mm at a speed of 10 m / min, and dried with a drum dryer to obtain a spunlace. The added specific energy was 0.24 kwh / kg.
Regarding the physical properties of the obtained spunlace, the geometric average of the breaking length was 2.6 km, the bending resistance was 70 mm, and the texture was ◯.

Example 2
NBKP (Hinton) was disaggregated with a tapi disaggregator and hand-rolled to obtain a 48 g / m ² sheet. In addition, 5% polylactic acid fiber and 1.3dtex x 12 mm polylactic acid fiber (aspect ratio: 1000) (Kanebo Synthetic Lactron) were added to the Tappi disintegrator so that the fiber concentration was 0.7%. Disaggregated. It was diluted to 5-fold, Nebazai the (PEO) was charged vs. 0.3% fiber, was obtained handsheets of basis weight 32 g / ^{m 2.} These sheets are stacked on a support so that the pulp sheet is on top, and at a speed of 10 m / min, a nozzle with a nozzle diameter of 0.1 mm and a nozzle interval of 1 mm is used to apply pressure 30 → 60 → 60 kg / cm ² and three times. Spunlace was obtained by entanglement and drying with a drum dryer. The added specific energy was 0.17 kwh / kg.
Regarding the physical properties of the obtained spunlace, the geometric average of the breaking length was 3.0 km, the bending resistance was 85 mm, and the texture was good.

Example 3
NBKP (Hinton) was disaggregated with a tapi disaggregator and hand-rolled to obtain a 35 g / m ² sheet. Furthermore, 5% polylactic acid fiber and 1.7dtex x 10mm polylactic acid fiber (aspect ratio: 800) (Unitika Terramac) from Polylactic Fiber were added to the tappy disintegrator so that the fiber concentration would be 0.7%. did. This was diluted 5 times, and 0.3% of fiber (PEO) was added to the fiber to obtain a handsheet having a basis weight of 35 g / m ² . These sheets are piled on the support so that the pulp sheet is on top, and the water is entangled four times at a speed of 10 m / min at a pressure of 30 kg / cm ² with a nozzle having a nozzle diameter of 0.1 mm and a nozzle interval of 0.6 mm. Spunlace was obtained by drying with a drum dryer. The added specific energy was 0.19 kwh / kg.
Regarding the physical properties of the obtained spunlace, the geometric average of the breaking length was 2.3 km, the bending resistance was 72 mm, and the texture was ◎.

Example 4
NBKP the (Hinton) loosened away in Tappi disintegrator to obtain handmade to the 26 g / ^{m 2} sheets this. Furthermore, in a tappi disintegrator, the dispersant is 5% to fiber, polylactic acid fiber 0.8 dtex × 10 mm (aspect ratio: 1100) (Terramac made by Unitika) and pulp, and polylactic acid: pulp = 8: 2 (weight ratio). In addition, the fiber concentration was 0.7%. It was diluted to 5-fold, Nebazai the (PEO) was charged vs. 0.3% fiber, was obtained handsheets of basis weight 44 g / ^{m 2.} These sheets are stacked on a support so that the pulp sheet is on top, and the water is entangled three times at a speed of 5 m / min at a pressure of 60 kg / cm ² with a nozzle having a nozzle diameter of 0.1 mm and a nozzle interval of 0.6 mm. Spunlace was obtained by drying with a drum dryer. The added specific energy was 0.82 kwh / kg.
Regarding the physical properties of the obtained spunlace, the geometric average of the breaking length was 3.2 km, the bending resistance was 75 mm, and the texture was ◎.

Comparative Example 1
NBKP (Hinton) was disaggregated with a tapi disaggregator and hand-rolled to obtain a 35 g / m ² sheet. Furthermore, 5% of the dispersant was added to the tap disintegrator and 1.7 dtex × 20 mm of polyester fiber (aspect ratio: 1600) (Teijin Tetoron Tepyrus) was added so that the fiber concentration would be 0.7% and disaggregated. . This was diluted 5 times, and 0.3% of fiber (PEO) was added to the fiber to obtain a handsheet having a basis weight of 35 g / m ² . These sheets are stacked on a support so that the pulp sheet is on top, and the water is entangled three times with a nozzle having a nozzle diameter of 0.1 mm and a nozzle interval of 1 mm at a pressure of 60 kg / cm ² at a speed of 5 m / min. Spunlace was obtained by drying with a dryer. The added specific energy was 0.49 kwh / kg.
Regarding the physical properties of the obtained spunlace, the geometric average of the breaking length was 3.2 km, the bending resistance was 90 mm, and the texture was Δ.

Comparative Example 2
NBKP (Hinton) was disaggregated with a tapi disaggregator and hand-rolled to obtain a 35 g / m ² sheet. Furthermore, 5% of the dispersant was added to the tapi disintegrator and 1.7 dtex × 10 mm of polyester fiber (aspect ratio: 800) (Teijin Tetoron Tepyrus) was added so that the fiber concentration would be 0.7% and disaggregated. . This was diluted 5 times, and 0.3% of fiber (PEO) was added to the fiber to obtain a handsheet having a basis weight of 35 g / m ² . These sheets are stacked on a support so that the pulp sheet is on top, and the water is entangled three times with a nozzle having a nozzle diameter of 0.1 mm and a nozzle interval of 1 mm at a pressure of 60 kg / cm ² at a speed of 5 m / min. Spunlace was obtained by drying with a dryer. The added specific energy was 0.49 kwh / kg.
Regarding the physical properties of the obtained spunlace, the geometric average of the breaking length was 0.5 km, the bending resistance was 70 mm, and the texture was ◯.

Comparative Example 3
NBKP (Hinton) was disaggregated with a tapi disaggregator and hand-rolled to obtain a 35 g / m ² sheet. Furthermore, the dispersion agent was 3% for the fiber, and the rayon fiber was 1.7 dtex × 10 mm (calculated on the assumption that the aspect ratio was 840 and the cross section was a circle) (Daiwabow Rayon SB) (Daiwa Bow Rayon SB) in the Tappi disintegrator. It was thrown in and disaggregated. This was diluted 5 times, and 0.3% of fiber (PEO) was added to the fiber to obtain a handsheet having a basis weight of 35 g / m ² . These sheets are stacked on a support so that the pulp sheet is on top, and the water is entangled three times with a nozzle having a nozzle diameter of 0.1 mm and a nozzle interval of 1 mm at a pressure of 60 kg / cm ² at a speed of 5 m / min. Spunlace was obtained by drying with a dryer. The added specific energy was 0.49 kwh / kg.
Regarding the physical properties of the obtained spunlace, the geometric average of the breaking length was 1.6 km, the bending resistance was 95 mm, and the texture was ◯.

Comparative Example 4
NBKP (Hinton) is disaggregated with a tappi disintegrator, and then the dispersant is 3% polylactic acid fiber, 1.3 dtex x 20 mm polylactic acid fiber (aspect ratio: 1700) (Kanebo synthetic fiber lactron) and pulp, and polylactic acid: The pulp was thrown in and disaggregated at 1: 1 (weight ratio). The fiber concentration was 0.5%. The polylactic acid fiber was warped. Thereafter, a spunlace was obtained by carrying out in the same manner as in Example 1 (additional specific energy: 0.24 kwh / kg).
Regarding the physical properties of the obtained spunlace, the geometric average of the breaking length was 1.5 km, the bending resistance was 76 mm, and the texture was x.

  As described above, the spunlace of the present invention has a uniform texture, is flexible, has practical strength even at a relatively low added specific energy, and is biodegradable by microorganisms after use. It can be widely used as a base material for medical and hygiene products and other industrial and household products.

Claims (2)

A web obtained by a wet papermaking method comprising a polylactic acid fiber and a pulp having a fiber length of 7 to 20 mm and an aspect ratio of 1200 or less is hydroentangled, and the geometric average of the longitudinal and lateral tear lengths given by Equation 1 is Span lace that is more than 2km.

The spunlace according to claim 1, wherein the additional specific energy of hydroentanglement given by Equation 2 is 0.1 to 0.3 kwh / kg.