JP5922368B2 - Long fiber elastic nonwoven fabric that has both fit and soft touch - Google Patents

Description

The present invention relates to a long fiber elastic spunbonded nonwoven fabrics having both fit and soft touch properties, more particularly, a composition comprising a thermoplastic polymer and a propylene-based elastomer polymer with heterogeneous composite spinning technology Spunbonding provides both fit and soft touch, disposable diapers, feminine hygiene products, personal hygiene products such as bands and bandages, gauze, sterile wraps and other hygiene items, and bedrooms use product relates to stretchable filaments nonwoven fabric applicable to a variety of products such as wipers.

  The cheap fiber and web manufacturing industry can easily produce a number of innovative products such as disposable diapers, children's swimming pants, children's defecation practice pants and adult urinary incontinence clothing It has become a well-developed industry. As the product has evolved and improved, fiber and web component requirements are also changing and increasing the demand for the material.

  As described above, the nonwoven fabric is widely used in various other fields. However, when it is actually used in a product in each field, it needs to be manufactured so as to have a property and a structure suitable for the use of the product.

  For example, a nonwoven fabric used for manufacturing an absorbent article is required to easily expand and contract in accordance with the movement of the body when the wearer wears or during wearing so as not to give the wearer a sense of incongruity. In addition, when used as a disposable diaper, the non-woven fabric has strength that does not break the sheet when stretched while maintaining stretchability, and these non-woven fabrics are mainly used in contact with the skin. Further, it is required that the touch is good.

  Thus, the nonwoven fabric has been developed to have a specific property in accordance with the characteristics of the application field, and in particular, the production of fibers and webs for expressing the elastic properties required for sanitary articles such as diapers. Various techniques have been proposed. For example, in Korean Laid-Open Patent Publication No. 2009-0128481, stretchable fibers and stretchable fibers are mixed and laminated and fixed by self-bonding by softening or melting. A method of imparting stretchability by subjecting the latent stretchable nonwoven fabric sheet to a stretched gear, and a crosslinked elastic film layer from a thermoplastic styrene block copolymer introduced in Korean Patent Publication No. 2007-701456. After forming and stretching, it is bonded to one or more nonwoven webs by a stretch-bonded laminate method. By discloses a method for providing a stretchable nonwoven fabric, a. However, in the case of the above technique, the film can be stretched only in the uniaxial direction, and in the case of the laminate method, it is unavoidable to perform a process of applying an adhesive to give adhesive properties with other materials. Therefore, there is a drawback that not only the processing steps are complicated but also the manufacturing cost increases.

  Because of the above-described problems, there is an interest in a method for developing elastic properties by introducing an appropriate elastic material, not equipment, when developing elastic properties. As an example of such a method, a method of producing stretchable fibers by spunbonding a polymer containing a thermoplastic polyurethane elastomer is disclosed (for example, see Patent Document 1 below). However, in the case of a polyurethane resin, the above method has a problem that it has a peculiar odor and a yellowing phenomenon occurs with time.

  On the other hand, various methods for improving the touch of the nonwoven fabric have been studied, but an ethylene-octene-based elastic polymer and a thermoplastic polyethylene (PE) -based copolymer or polypropylene (PP) are used as raw materials. And the method of manufacturing the fiber and web which have non-adhesive touch property using a different component composite spinning technique is disclosed (for example, refer patent document 2 below). However, the elastic raw material used in the above method has high viscosity and melt elasticity at high temperatures, so that when the production is continued over a long period of time due to an increase in the pressure of the spinning nozzle during production, Various problems such as reduction occur, and the raw material price is also expensive, so that there is a disadvantage that the commercial property is inferior. Furthermore, in the case of the ethylene-octene-based elastic polymer, when a disposable sanitary product is applied, a load increased during user's urination or defecation, that is, deformation due to a low external load is large, and drooping occurs when worn. There is a drawback that the user's feeling of wear or fit is reduced.

  Thus, polymer manufacturers can perform melt processing in a manner very similar to traditional polyolefins, but have elastic properties close to traditional rubber and textile elasticity and into the disposable fibers and webs described above. Highly cost-effective, relatively inexpensive and novel olefinic propylene-based elastomeric polymers have been commercially available. For example, the following Patent Document 5 discloses a non-woven fabric using a propylene-based elastomer polymer. In the case of the patent, 30 wt% erucic acid amide and 70 wt% propylene-based elastomer polymer are disclosed. Attempts have been made to reduce the sticky touch of elastic raw materials. However, even in the case of the above technique, since it is not possible to increase the content of the elastic raw material due to the high content of erucamide, which is a high slip agent, it is not possible to express excellent stretchability that is an elastic property, There is a problem that the elastic modulus cannot be controlled.

  As mentioned above, the acceptability of the olefin polymer for many applications of conventional non-adhesive elastic properties and non-wovens that can withstand deformation against a given external load has been hampered for the following reasons. . That is, the first reason is that it has adhesiveness and inconvenience that prevent application of fibers and webs to the touch application. The second reason is that when the content of elastic raw material is increased in order to increase physical properties such as elastic recovery force, the elastic raw material has high viscosity and melt elasticity due to its characteristics and has self-adhesiveness. This self-adhesion will continue to contaminate the device. In addition, contamination of such an apparatus leads to production interruption, resulting in a loss of high cost. In particular, the elastic nonwoven fabric needs to be controlled with respect to a predetermined external load deformation for application to a disposable diaper. This is because.

  Therefore, the present inventors have recognized the above-described problem and the cause thereof, and based on this, as a result of intensive research on a method that can solve the conventional problems, the present invention has been completed. .

Republic of Korea Published Patent No. 2005-0088361 Republic of Korea Published Patent No. 2007-0085091 Korean Published Patent No. 2007-0087619 Republic of Korea Published Patent No. 2006-0090838 Korean Published Patent No. 2010-0080625

  The present invention has been made in view of the above-described conventional technical problems. More specifically, the increase in the elastic content for the increase in the elastic properties usually causes a large degree of deformation even with a low external load. There is a drawback that the feeling of wear or fit of the user is lowered, such as sagging when worn, and the high viscosity and melt elasticity of the elastic material prevents high-speed spinning of the continuous elastic polymer fiber, Furthermore, there is a problem that the adhesive property of the elastic material is not good for the user's skin contact. Therefore, a main object of the present invention is to provide a long-fiber elastic nonwoven fabric that solves the technical problems described above and has both fit and soft touch.

  Another object of the present invention is a method for more easily producing a long-fiber elastic nonwoven fabric having both a fitting property with improved workability and a soft feel by smoothly performing various work processes including spinnability. Is to provide. More specifically, when manufacturing an elastic nonwoven fabric having a soft touch, an elastic raw material is introduced into the center of the fiber, and a thermoplastic olefin having a soft touch is introduced into the fiber surface, and appropriate manufacturing equipment is introduced. This eliminates the problem of elastic raw materials sticking to the manufacturing equipment, and also, by performing different component composite spinning by finding the optimal fit and expansion ratio by changing the content ratio of elastic raw materials. It is providing the manufacturing method which has property.

  Still another object of the present invention is to provide a long-fiber elastic non-woven fabric that has an elastic non-woven fabric that can be controlled against deformation of a predetermined external load and a soft touch for application to a disposable diaper. There is a place to do.

  The present invention also aims to achieve, in addition to the above-described specific objects, other objects that are easily derived from the general techniques of this specification by those of ordinary skill in the art.

  The object of the present invention is to maintain a high spinning speed by utilizing heterogeneous composite yarns such as an elastic propylene-based elastomer polymer and a thermoplastic olefin. Moreover, this can be achieved by providing a fiber having excellent elasticity recovery and soft touch.

In order to achieve the above object, the long fiber elastic nonwoven fabric having both fit and soft touch according to the present invention has a melt index at 190 ° C. of 25 to 35 g / 10 minutes and a density of 0.9515. A component polymer constituting at least a part of the fiber surface containing high density polyethylene (HDPE) of 0.9565 g / cm ³ forms a sheath portion, and a B component polymer containing a propylene-based elastomer polymer is a core portion. forming an all SANYO formed by core-sheath composite long fibers, when measurement was carried out using 100% 1-cycle history test, the elastic modulus for the machine direction (MD) 1.0~1.8kg characterized in that it is a / mm ^2.

  According to another configuration of the present invention, the ratio of the sheath to the core is 30/70 to 0/100, preferably 20/80 to the sheath / core, based on the total weight of the fiber. 1/99, more preferably 10/90 to 5/95.

  According to still another configuration of the present invention, the elastic nonwoven fabric has a permanent deformation rate of 30% or less when measured using a 100% 1-cycle history test.

According to still another configuration of the present invention, the elastic nonwoven fabric has a basis weight of 10 to 200 g / m ² .

  According to still another configuration of the present invention, the fiber diameter of the different component material is 15 to 35 μm.

  To achieve other objects of the present invention, absorbent articles such as disposable diapers and sanitary napkins, personal hygiene products, cleaning products such as wipers, medical products such as gauze and bandages such as masks, etc. It is manufactured from the nonwoven fabric containing the said nonwoven fabric which concerns on a structure, It is characterized by the above-mentioned.

The long-fiber elastic nonwoven fabric having the above-described configuration and having the fit and soft touch of the present invention is improved to have both the fit and soft touch by a simple manufacturing process, and is used in many industries. For example, the woven fabric having the fit, excellent stretchability and soft touch of the present invention can be used for the manufacture of sanitary goods. Or personal hygiene products, such as diaper fastening tabs, side panels, foot cuffs, face sheets, back sheets, fastening tapes, feminine hygiene products, swimwear, infant pull-up pants, urinary incontinence clothing components, As a dynamic or stretchable component of these products, including but not limited to elastic fixation bands It can be used. In other embodiments, the fibers and nonwovens can be used in the manufacture of other protective garments or covers, such as medical jackets or aprons, surgical drapes, sterile wraps, wipers, beddings, or similar disposable medical and covers. It is. Also, the application fields of these materials have been used protective covers, household furniture such as bedding, anti-slip pads for walls, wall coverings, floor coverings, window shades, streams and traditional fabrics. It can be used in any other field.

It is the schematic of the different component spinning system which is used for manufacture of the long-fiber elastic nonwoven fabric which has a fit and soft touch property based on this invention, and forms a spun bond nonwoven fabric. It is the schematic of the air injection apparatus which uses according to this invention and performs isolation | separation of a laminated nonwoven fabric and a belt easily.

Prior to further elaborating the present invention with a preferred embodiment, the test procedures and terminology used in the present invention are summarized as follows:
[Examination procedure]
Measurement test of permanent elongation (%) and elastic modulus (kg / mm ² ):
Based on the ASTM D882 method, the sample was dropped between line-contact grips activated by air pressure. The pressure was adjusted to prevent slippage (usually 50-100 psi). The crosshead speed was set to 300 mm / min. The crosshead was stretched to 100% deformation and returned to 0% deformation at the same crosshead speed. The elastic recovery force was defined by Equation 1 below. At this time, fresh or non-old samples were used as samples.

Permanent elongation (%) = (ΔL / Li) × 100: Formula 1
Here, ΔL is Lf-Li, Lf is the length after fiber drawing, and Li is the length before fiber drawing.

  The elastic modulus can be measured under the same test conditions as when measuring the permanent elongation, and the elastic modulus value can be obtained by the following Hooke's law.

ここで、σは外部応力であり、εは変形長さである。

Here, σ is an external stress, and ε is a deformation length.

touch:
The touch of the spunbonded nonwoven fabric was evaluated by 30 testers. This evaluation was performed according to the following criteria.
A: When 27 or more of 30 testers answered that the non-woven fabric had no stickiness and was soft to the touch.
B: 26 to 21 out of 30 testers replied that the non-woven fabric had no stickiness and was soft to the touch.
C: When 30 to 15 testers answered that the non-woven fabric was not sticky and feels good.
D: 14 to 9 out of 30 testers answered that the non-woven fabric was not sticky and feels good.
E: When 8 to 0 of 30 testers replied that the non-woven fabric was not sticky and was soft to the touch.

Scanning electron microscope:
Scanning electron microscope fibers and non-woven samples were placed on an aluminum sample stage with carbon black-filled tape and copper tape. Thereafter, the mounted sample was subjected to 100 using an SPI-module sputter coater (model number 11430) manufactured by Structure Probe, Inc., located in Westchester, Massachusetts, USA, with an argon gas supplier and a vacuum pump. Coated with ~ 200 kg of platinum. The coated samples were then examined by S4100 scanning electron microscope with a field effect gun, supplied by Hitachi America Yale Tide (located in Shauborg, Illinois, USA). Samples were examined in secondary electron video mode using an accelerating voltage of 3-5 kV and video was collected using a digital video capture system.

  The term "elastic" or "stretchable" as used in the present invention is stretchable when energized, i.e. stretchable to at least 60% and up to at least 50% of the stretched state when the stretching force is released. Any substance that returns to its original state. Many stretchable materials are much more than 60% (ie, much more than 160% of the relaxed length), eg, stretchable to 100% or more, many of which are substantially Thus, these initial relaxation lengths are restored to, for example, 105% of these initial relaxation lengths when the extension force is released.

  The term “stretchable or elastic web” means that the “permanent elongation” or “elastic recovery rate” is 30% or less when measured to 100% deformation rate by the 1-cycle test described above in the test procedure. A web sample having a value.

  Further, the term “elastic modulus” used in the present invention indicates the ratio of stress to deformation with respect to deformation of an object within the limit, and is a numerical value indicating the elastic durability of an arbitrary material.

  As used herein, the term “nonwoven or non-woven” means a fiber or filament web formed by means other than knitting or weaving and containing bonds between some or all of the fibers or filaments; Such a bond can be formed, for example, by thermal, adhesive or mechanical means such as twisting. Conventional nonwoven fabrics are formed by spunbond, meltblown, carding, wet laying and air laying processes.

  The term “spunbond” as used in the present invention is usually collected on a surface formed from streaks that have been quenched and stretched by high-speed air by melt extrusion of a polymer extrudate, often a pattern of heat and pressure. It refers to a non-woven or non-woven fabric of filaments reinforced with filaments that have been joined by a modified application.

  The other terms “composite” and “multicomponent” used in the present invention are used interchangeably and refer to two or more individual sections occupied by separate polymer components depending on the total length of the fiber or filament. A fiber or filament formed by assembling multiple extrudates to each inviting fiber or filament. The cross section of the fiber can take various arrangements such as a side-by-side shape, a pie shape, a sheath core shape, an eccentric sheath core shape, and a sea island shape. Of particular interest in the present invention is the sheath-core arrangement.

  Based on the test procedure and terminology used in the present invention, preferred embodiments of the present invention will be described below in detail with reference to the accompanying drawings.

According to a preferred embodiment of the present invention, the component A of the present invention may be, for example, a polyethylene homopolymer (MM810 grade) manufactured by SK, but the present invention is not limited thereto. For polyethylene homopolymer, the density is preferably about 0.9450 g / cm ^{3 to} 0.9650 g / cm ³ , more preferably about 0.9505 to 0.9575 g / cm ³ .

According to another preferred embodiment of the present invention, the propylene-based elastomer polymer of component B of the present invention is a VISTAMAXX elastomer manufactured by Exxon-Mobile, but is not limited to these. A propylene-based elastomer polymer obtained by copolymerizing tic polypropylene with ethylene as a base material can be used. The density range is preferably 0.855 to 0.910 g / cm ³ and preferably about 0.860 to 0.870 g / cm ³ for some applications.

  Next, the manufacturing process of the stretchable nonwoven fabric according to the present invention will be described in detail.

  FIG. 1 is a schematic diagram of a hetero-component spinning system used to produce a long-fiber elastic nonwoven fabric having both fit and soft touch according to the present invention to form a spunbond nonwoven fabric, and FIG. 2 is according to the present invention. 1 is a schematic view of an air injection device that is used to facilitate separation of a laminated nonwoven fabric and a belt.

  Referring to FIG. 1, which shows an exemplary manufacturing process for a nonwoven web according to the present invention, the stretch nonwoven fabric according to the present invention melts the long-fiber spunbond nonwoven fabric into the heterogeneous polymer in the illustrated process line. To start with. At this time, the different component polymer is produced by kneading the melted polymers in the respective extruders 1 and 2. The polymer A component is supplied from the first hopper 1-1 to the extruder, and the polymer B component is optionally supplied from the second hopper 2-1 to the extruder. The molten component polymer is conveyed from the separate extruders 1 and 2 to the spin beam 3 via the respective polymer conduits. The form of the spinneret for spinning the heterocomponent filaments is known to those skilled in the art, and therefore detailed description thereof is omitted in the present invention. Thereafter, in the process line A, the filament spun so as to be adjacent to the filament curtain extending from the spinning nozzle 4 is solidified by the cooling air sprayed through the honeycomb-shaped cooling chamber 5. According to one embodiment of the present invention, when a multicomponent filament composed of an A polymer in the sheath portion and a B component polymer in the core portion is manufactured, the temperature of the cooling chamber portion needs to be controlled low. The reason for this is that if the temperature exceeds a predetermined level, filaments stick together in the cooling chamber to prevent continuous sheet production, and the physical properties are greatly reduced because the stretching is not sufficient. For this reason, the temperature of the chamber portion is 10 to 20 ° C., preferably 12 to 18 ° C., and most preferably 14 to 16 ° C.

In the case of cooling air in the cooling chamber 5, the filament discharged from the spinning nozzle 4 is stretched by the pressure of the air blown from the upper part and the air sucked in the lower part of the conveyor belt 9, and is a porous special conveyor having excellent separability. A web is formed by being laminated on the belt 9 at a predetermined weight. In the present invention, the composite spunbond long fiber nonwoven fabric preferably has a basis weight of 10 to 200 g / m ² and a fiber diameter of 15 to 35 μm.

  Referring to FIG. 2, the non-woven fabric according to the present invention has a rectangular air injection device B-3 in which a large number of holes are opened at the position of the reference numeral 10 between the conveyor belt and the calender roll before thermal bonding. A predetermined air pressure is jetted upward at the upper and lower portions of the belt to separate the laminated nonwoven fabric B-2 and the conveyor belt B-1. The air injection speed of the air injection device needs to be maintained at 5 to 30 m / s. When the air injection speed is less than 5 m / s, the phase separation between the belt and the nonwoven fabric sheet is not smoothly performed, and when it exceeds 30 m / s, the air pressure is too strong and the sheet comes off. It is not preferable.

  The nonwoven fabric laminated in this way is heat sealed to provide mechanical properties and form stability. In other words, heat and pressure are applied through the heat calender roll and heat-adhered to form a sheet. At this time, the structure of the calender roll does not limit the bonding area, but one is usually formed on the surface of the embossing roll 11 having a bonding area of 10 to 20%, and the other is a roll having a smooth surface. It consists of twelve. If the roll temperature exceeds a predetermined level, the sheet is thermally fused to the heating roll, making it impossible to produce the sheet, and if the temperature is too low, the physical properties of the sheet will be reduced. For this reason, according to a preferred embodiment of the present invention, the thermal temperature of the roll is preferably 80 ° C to 120 ° C, more preferably 90 ° C to 110 ° C. It should be noted that an excessive roll pressure needs to be controlled to a predetermined level or less because a soft sheet is fused to the roll.

  After heat-bonding in this way, it is wound using a winder 14 for taking in the nonwoven fabric 13. In this case, normal winding such that the stretchability of the nonwoven fabric increases due to the properties of the B polymer in the core and the winding speed of the winder 14 is faster than the speed of the embossing roll 11 that thermally bonds the nonwoven fabric. When winding by the method, width shrinkage occurs, and winding is performed nonuniformly, which is not preferable. For this reason, the winding speed of the winder 14 is preferably reduced to a ratio of 80 to 99%, more preferably 85 to 97%, and most preferably 87 to 95%, compared to the rotational speed of the embossing roll. There is a need.

  The elastic copolymer as a raw material used in the present invention is particularly made by Exxon-Mobile, has a melt index (MI) at 230 ° C. of 28 g / 10 min, and a density of 0.860-0. 870 is a propylene-based elastomer polymer.

  At this time, the constituent ratio of the high-density polyethylene which is the sheath part of the long-fiber nonwoven fabric filament and the propylene-based elastomer polymer which is the core part is 30/70 to 0 in the sheath part / core part based on the total weight of the fibers. / 100, preferably 20/80 to 1/99, and more preferably 10/90 to 5/95. If the content ratio of the high-density polyethylene as the sheath and the propylene-based elastomer polymer as the core increases to a predetermined level, the fit and elastic recovery Although the force is good, if it rises too much, stickiness, which is a characteristic of an elastic body, will occur, which is not preferable because there is a disadvantage that it is stuck to a porous continuous belt and a heat calender roll and production is not performed. .

  Moreover, since the stretchability of the nonwoven fabric increases due to the properties of the B component polymer in the core, as described above, winding conditions different from the normal method for the winding section are required.

  The following examples are for the purpose of further illustrating the present invention, and it goes without saying that the scope of the present invention is not limited thereto.

Example 1
Using Reicofil-3.1, Bicomponent system equipment manufactured by Reifenhauser, Germany, the conditions of the extruder are 150 mm around the outer wall, L / D30, and the nozzle conditions are 0.6 mm, L / D4, per unit meter A different component spinning line with 5000 holes was used. The conveyor belt used was Suprastat 4000 manufactured by COFPA with an air permeability unit of 8910 m ³ / m ² / Hr (100 Pa) and was used to facilitate separation of the fiber sheet and belt.

As the raw material used, the component A (high grade polyethylene (HDPE) having a melt index of 28 g / 10 min at 190 ° C. and a density of 0.954 g / cm ³ per sheath part, manufactured by SK, grade : MM810), and a propylene-based elastomer polymer (Vistamaxx, grade: VM2125) manufactured by Exxon-Mobile Co. was used for the core. An elastic body having a melt index of 28 g / 10 min at 230 ° C. and a density of 0.868 g / cm ³ was used.

  The ratio of the different component spinning line was such that the weight ratio of the sheath / core was 20/80 of the total fibers. The air discharge speed of the rectangular air injection device used for sheet separation was maintained at about 20 m / s. The temperature of the embossing roll was 100 ° C., and after heat-bonding at a pressure of 50 N / mm to produce a nonwoven fabric having a basic weight of 30 gsm, the nonwoven fabric was wound at an embossing roll rotation speed of X0.90 rpm. .

  With respect to the nonwoven fabric sheet formed from the different component fibers, the permanent elongation and the elastic modulus were measured in a stretched state of 100%, and the touch of the nonwoven fabric was evaluated. The results are shown in Table 1 below.

Example 2
A nonwoven fabric was produced in the same manner as in Example 1 except that the sheath / core raw material ratio was changed to 10/90 of the total fibers.

Example 3
A nonwoven fabric was produced in the same manner as in Example 1 except that the sheath / core raw material ratio was changed to 5/95 of the total fibers.

Comparative Example 1
A nonwoven fabric was produced in the same manner as in Example 1 except that the air discharge speed of the air injection device for separating the sheet was set to less than 5 m / s.

Comparative Example 2
The raw material material of the sheath is applied to a polypropylene (PP) A component (grade: SFR171-H manufactured by Honam Petrochemical Co., Ltd.) having a melt index of 34 g / 10 min at 230 ° C. and a density of 0.900 g / cm ^3. A nonwoven fabric was produced in the same manner as in Example 1 except that.

Comparative Example 3
A nonwoven fabric having a basis weight of 30 gsm was manufactured in the same manner as in Example 1 except that the quenching temperature of the fiber cooling part was set to 25 ° C. and the fiber spun from the nozzle was cooled.

Comparative Example 4
A nonwoven fabric having a basis weight of 30 gsm was produced in the same manner as in Example 1 except that the temperature of the nonwoven fabric embossing roll was 130 ° C. and heat bonding was performed at a pressure of 50 N / mm.

Comparative Example 5
A nonwoven fabric having a basis weight of 30 gsm was manufactured in the same manner as in Example 1 except that the temperature of the nonwoven fabric embossing roll was 100 ° C. and heat bonding was performed at a pressure of 100 N / mm.

Comparative Example 6
A nonwoven fabric was manufactured in the same manner as in Example 1 except that the nonwoven fabric was wound at an embossing roll rotation speed of 1.0 rpm.

Changes in permanent elongation (%), elastic modulus, and feel

  As apparent from Table 1, as the ratio of the elastic raw material on the core side is increased from 20/80 to 5/95 from the ratio of the sheath part / core part, the elastic characteristics increase and the permanent elongation and elastic modulus are increased. It turns out that becomes low.

  However, in Comparative Example 1, when the air injection speed of the air injection device for easy separation of the sheets is maintained at less than 5 m / s, the sheets stick to the belt, and the sheets can be produced. There wasn't.

  In addition, when the results of the tester analysis of how the fiber and the nonwoven fabric are touched when the sheath material in Example 1 and Comparative Example 2 are changed, PE is applied to the surface of the filament. It can be seen that the case of using it is evaluated that a much softer touch is obtained compared to the case of using PP.

  In Comparative Example 3, when the quenching temperature of the fiber cooling section is set to a high level (25 ° C.), the spun filament is not sufficiently cooled, and yarn breakage occurs or the chamber is spun. The sheet could not be produced continuously.

  Further, as is clear from Comparative Examples 4 and 5, in the Comparative Example in which the calendar temperature and the pressure conditions were different, the work could not be performed by being fused to the calendar roll. In Comparative Example 6, when the winding condition was not changed, the sheet became narrow and the winding was performed unevenly, so that continuous production was impossible.

1, 2, ... Extruder,
3 ... Spin beam,
4 ... Spinning nozzle,
5 ... Cooling chamber,
13 ... Nonwoven fabric,
14 ... winding machine,

Claims (7)

Component A constituting at least part of the fiber surface containing high density polyethylene (HDPE) having a melt index at 190 ° C. of 25 to 35 g / 10 min and a density of 0.9515 to 0.9565 g / cm ³ polymer forms a sheath state, and are not formed by the core-sheath composite long fibers B component polymer comprising propylene-based elastomer polymer to form a core portion,
When measured using a 100% 1-cycle history test, the elastic modulus with respect to the machine direction (MD) is 1.0 to 1.8 kg / mm ² , and fit and soft touch characteristics are characterized. A long-fiber elastic nonwoven fabric.   2. The fit and soft touch according to claim 1, wherein the ratio of the sheath to the core has a sheath / core of 20/80 to 1/99 based on the total weight of the fibers. A long-fiber elastic nonwoven fabric.   3. The fit and softness according to claim 1, wherein the elastic nonwoven fabric has a permanent deformation rate of 30% or less when measured using a 100% 1-cycle history test. 4. A long-fiber elastic nonwoven fabric that also has a soft touch. The long-fiber elastic nonwoven fabric having both fit and soft touch according to claim 1, wherein the elastic nonwoven fabric has a basis weight of 10 to 200 g / m ² .   The fiber diameter of the different component material is 15 to 35 m, The long fiber elastic nonwoven fabric having both fit and soft touch according to claim 1. An extensible laminate comprising the nonwoven fabric or non-woven fabric according to any one of claims 1 to 5 . The nonwoven fabric according to any one of claims 1 to 5, which is used for absorbent articles such as disposable diapers and sanitary napkins, wiper cleaning articles, mask gauze and bandages.

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