JP3045343B2 - Laminated long-fiber nonwoven fabric and method for producing the same - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a laminated long-fiber nonwoven fabric having a very soft feel and a high strength, and a method for producing the same.

[0002]

2. Description of the Related Art Currently, nonwoven fabrics are widely used in various applications such as sanitary materials, industrial materials, civil engineering materials, and general living materials. Nonwoven fabrics include those composed of short fibers and those composed of long fibers, and the latter is used for applications requiring strength because it is stronger than the former. However, the long-fiber nonwoven fabric has high strength, but has a drawback that the feel is hard or the feel is poor.

In order to soften the feel of the long-fiber nonwoven fabric or to improve the feel, it is conceivable to reduce the fineness of long fibers constituting the nonwoven fabric. However, there is a certain limit in reducing the fineness of long fibers. That is, for example, it was difficult to reduce the fineness to 1 denier or less for reasons of manufacturing long fibers. Therefore, although the texture of the long-fiber nonwoven fabric can be softened to some extent, it is difficult to further soften the texture.

[0004]

For this reason, the present inventors have tried to obtain a long-fiber nonwoven fabric having a softer feeling by examining the raw material of the long fiber. As a result, by using a special copolymer, that is, a copolymer of ethylene and octene-1, as a material of the long fiber, a long fiber nonwoven fabric with a soft feeling was successfully obtained. However, long fibers made of this special copolymer have insufficient strength, and it has been difficult to obtain a high-strength long-fiber nonwoven fabric.

Accordingly, the present inventors have tried to impart high strength by joining a high-strength nonwoven fabric to this long-fiber nonwoven fabric to form a laminated long-fiber nonwoven fabric. That is, a web made of other long fibers having relatively high strength is laminated on the web made of the long fibers, and the long fibers and the other long fibers are joined by heat fusion. However, the long fibers made of the special copolymer do not bond well to any long fibers. That is, when the long fiber and the other long fiber are heat-sealed, the long fiber shrinks, and the obtained laminated long-fiber nonwoven fabric becomes wrinkled, or the two long fibers are joined with a high bonding force. There was a disadvantage that heat fusion was not possible.

[0006] For this reason, the present inventors have developed a long fiber which is excellently heat-fused with a long fiber made of the above-mentioned special copolymer and which is bonded with a high bonding force, and reached the present invention. It was done. In other words, the present invention, by combining a web composed of long fibers made of a special copolymer as a material, and a web of other high-strength long fibers that are well bonded to the long fibers, They have succeeded in obtaining a long-fiber nonwoven fabric that has both a very soft feel and high strength.

[0007]

That is, the present invention provides a layer A composed of long fibers A mainly composed of linear low-density polyethylene, and a layer B composed of core-sheath type composite long fibers B. Wherein the long fiber A and the core-sheath type composite long fiber B are heat-fused, and the A layer and the B layer are joined to each other. Low density polyethylene is 99
A copolymer of about 90% by weight of ethylene and 1 to 10% by weight of octene-1, and a sheath component of the core-sheath type composite long fiber,
At the melting point of the linear low-density polyethylene, at least a softening polyethylene, and the core component is polypropylene, a laminated long-fiber nonwoven fabric,
And a method for producing the nonwoven fabric.

The laminated long-fiber nonwoven fabric according to the present invention comprises an A layer having a very soft feel and a B layer exhibiting high strength. The A layer is composed of long fibers A, and the long fibers A are mainly composed of linear low-density polyethylene. This linear low density polyethylene has 99
It is a copolymer of 9090% by weight of ethylene and 1-10% by weight of octene-1. 99-90% by weight of such a copolymer
Of ethylene and 1 to 10% by weight of octene-1
It can be obtained by causing a polymerization reaction. If the amount of octene-1 is less than 1% by weight, the rigidity of the obtained long fiber composed of linear low-density polyethylene increases, and it becomes impossible to form a soft feeling A layer, which is not preferable. Conversely, if the amount of octene-1 exceeds 10% by weight, it is difficult to obtain long fibers of fine fineness, and it is difficult to obtain the A layer having a soft feeling, which is not preferable.

The long fiber A is mainly composed of a copolymer of ethylene and octene-1, and may contain another polymer in addition to the copolymer. As the other polymer, various conventionally known polymers can be used, and it is particularly preferable to use polypropylene. When mixing the polypropylene, the mixing amount is preferably not more than 20% by weight. That is, it is preferable that 80% by weight or more of the copolymer and 20% by weight or less of the polypropylene are mixed to form the long fiber A. The reason for mixing polypropylene is
This is for improving the spinnability of the copolymer. If the mixing amount of the polypropylene exceeds 20% by weight, the fiber-forming property of the copolymer tends to be poor. As the polypropylene used here, a conventionally known polypropylene can be used, or a polypropylene obtained by copolymerizing a small amount of ethylene, butene, or the like with polypropylene can also be used. Needless to say, the long fiber A may be formed only of a copolymer of ethylene and octene-1.

The layer B of the laminated long-fiber nonwoven fabric according to the present invention comprises:
It is composed of a core-sheath type composite long fiber B. The sheath component is made of at least softening polyethylene at the melting point of the linear low-density polyethylene. That is, at the melting point of linear low density polyethylene,
It is made of softening or melting polyethylene. This is because the sheath component and the long fiber A are welded to each other,
This is because the sheath-type composite long fiber B and the long fiber A are thermally fused. At the melting point of linear low-density polyethylene, if the sheath component is composed of polyethylene that does not soften, the core-
It is not preferable because the heat fusion between the sheath type composite long fiber B and the long fiber A cannot be sufficiently performed. Specific examples of the polymer used as the sheath component include the same linear low-density polyethylene or high-density polyethylene as the main component of the long fiber A. In addition, the measuring method of the melting point of linear low-density polyethylene is as follows. That is, using a DSC-2 differential scanning calorimeter manufactured by Perkin Elmer,
The temperature showing the maximum value of the melting absorption peak when measured at 20 ° C./min was defined as the melting point. In the present invention, the melting point of a polymer other than the linear low-density polyethylene was also measured by this method.

As the core component of the core-sheath type composite long fiber B, polypropylene is used. Polypropylene is hard to soften at the melting point or softening temperature of the sheath component or long fiber A. Therefore, even after the core-sheath type composite long fiber B and the long fiber A are heat-sealed, in the heat-sealed area, the core component exists as a skeleton component in the B layer. . The presence of the skeletal component can impart high strength to the laminated long-fiber nonwoven fabric. As the polypropylene used as the core component, a conventionally known polypropylene can be used. Further, polypropylene obtained by copolymerizing a small amount of ethylene, butene, or the like with polypropylene can also be used. In addition, the composite ratio of the core component and the sheath component of the core-sheath type composite long fiber B can be arbitrarily determined as desired. Generally, it can be arbitrarily determined within the range of core component: sheath component = 1: 0.25 to 4 (weight ratio).

A layer composed of the long fiber A and a core
The layer B composed of the sheath type composite long fiber B is laminated, joined and integrated. In the lamination of the layer A and the layer B, the weight ratio can be arbitrarily determined. In particular, when trying to obtain a laminated long-fiber nonwoven fabric with an emphasis on flexibility, increasing the weight ratio of layer A and conversely, when obtaining a laminated long-fiber nonwoven fabric with a high emphasis on strength It is preferable to increase the weight ratio of the B layer. The bonding of the layer A and the layer B is performed by heat fusion between the long fiber A and the core-sheath type composite long fiber B. In this heat fusion, the long fiber A is melted or softened, and the sheath component of the core-sheath type composite long fiber B is melted or softened, so that both fibers are fixed. The heat fusion may be performed over the entire lamination surface of the laminated long-fiber nonwoven fabric, or may be performed in a fixed area such as a dot or a line disposed at a constant interval. Is also good. In particular, the latter heat-sealing is preferable because the non-heat-sealed area remains, so that the flexibility of the laminated long-fiber nonwoven fabric is not hindered. In this case, it is preferable that the sum of the areas of the heat-fused certain areas is 4 to 40% with respect to the total area of the laminated long-fiber nonwoven fabric. If the total area is less than 4%, the number of the heat-sealed areas is too small, and the bonding strength between the A layer and the B layer is not sufficient, and the layers tend to peel. If the total area exceeds 40%, the flexibility of the laminated long-fiber nonwoven fabric tends to be impaired. The laminated long-fiber nonwoven fabric according to the present invention may be composed of the A layer and the B layer, or may have different layers together with the A layer and the B layer.

The fineness of the long fiber A and the core-sheath type composite long fiber B used in the present invention is preferably 5 denier or less. If the fineness of the long fiber A or the core-sheath type composite long fiber B exceeds 5 denier, the feeling of the laminated long fiber nonwoven fabric tends to be hard. The fineness of the long fiber A and the core-sheath type composite long fiber B is measured by the following measuring method. That is, the diameter of the fiber is measured using a universal projector, and the fiber is converted to denier based on the diameter and after performing density correction. In addition, the long fiber A and the core-sheath type composite long fiber B include lubricants, pigments, stabilizers, flame retardants, etc. in order to modify the fibers, in addition to the various fiber-forming polymers. It may be attached or contained. The cross-sectional shapes of the long fibers A and the core-sheath type composite long fibers B are generally circular, but may be other multi-leaf shapes, hollow shapes, or the like.

Next, a method for producing a laminated long-fiber nonwoven fabric according to the present invention will be described. First, a linear low-density polyethylene comprising a copolymer of 99 to 90% by weight of ethylene and 1 to 10% by weight of octene-1 is prepared. It is preferable to use the linear low-density polyethylene having the following characteristics in consideration of melt spinnability and the like. That is, the melt index value is 20 to 80 g / 10 min, and the density is 0.90.
It is preferably between 0 and 0.940 g / cc. If the melt index value is less than 20 g / 10 minutes, high-speed spinning cannot be easily performed unless the melt spinning temperature is extremely high, and it becomes difficult to form the long fiber A rationally. In addition, when high-speed spinning is performed at an extremely high temperature, dirt due to linear low-density polyethylene tends to adhere to the spinning nozzle, making continuous production difficult. Conversely, if the melt index value is 80
If the amount exceeds g / 10 minutes, the strength of the obtained long fiber A tends to decrease, and the strength of the laminated long fiber nonwoven fabric tends to decrease. When the density of the linear low-density polyethylene is less than 0.900, the strength of the obtained long fiber A tends to decrease. Conversely, when the density of the linear low-density polyethylene exceeds 0.940, the rigidity of the obtained long fiber A increases, and the feeling of the A layer tends to be hard.
In addition, the above-mentioned melt index value is D-value of ASTM.
It is measured by the method specified in 1238 (E).

The linear low-density polyethylene as described above is used alone or mixed with another polymer and melt-spun to obtain a long fiber A.
Get. As the other polymer to be mixed, any polymer can be adopted, but it is particularly preferable to mix polypropylene having a melt flow rate of 10 to 70 g / 10 min. When the melt flow rate value is less than 10 g / 10 minutes, it becomes difficult to uniformly mix the linear low-density polyethylene and the polypropylene, and there is a tendency that the spinnability deteriorates. Conversely, if the melt flow rate exceeds 70 g / 10 minutes, the strength of the obtained long fiber A tends to decrease.
This melt flow rate value is based on ASTM D-1238.
It is measured by the method specified in (L). When mixing the linear low-density polyethylene with the polypropylene, it is preferable to mix 80% by weight or more of the linear low-density polyethylene with 20% by weight or less of the polypropylene. If you mix more than 20% by weight of polypropylene,
There is a tendency that the spinnability of the long fiber A decreases. After the long fiber A as described above is melt-spun, it is accumulated on a conveyor or the like to form the A layer. The spinning temperature for obtaining the long fiber A is 22
The temperature is preferably about 0 to 265 ° C, particularly preferably about 230 to 255 ° C. If the spinning is carried out at a temperature higher than this temperature, the surface of the spinneret becomes liable to be stained, and if the spinning is operated for a long time, thread breakage occurs with time, making it difficult to obtain a uniform A layer. In addition, if the spinning is performed at a temperature lower than this temperature, it is difficult to perform stable melt spinning.

In addition to the layer A, a core-sheath type composite long fiber B
To form a B layer. Core-sheath type composite long fiber B
At the melting point of the linear low-density polyethylene used to obtain the long fiber A, by using at least softening, that is, softening or melting polyethylene as a sheath component, using polypropylene as a core component, and melt composite spinning, It is formed. Specific examples of the polyethylene used as the sheath component include a linear low-density polyethylene and a high-density polyethylene used for obtaining the long fiber A. As the polypropylene used as the core component, it is preferable to use a polypropylene having a melt flow rate of 10 to 70 g / 10 minutes. If the melt flow rate value is less than 10 g / 10 minutes, high-speed spinning cannot be easily performed unless the melt spinning temperature is extremely high, and it becomes difficult to reasonably form the core-sheath type composite filament B. In addition, when high-speed spinning is performed at an extremely high temperature, dirt due to polypropylene tends to adhere to the spinning nozzle, making continuous production difficult. Conversely, the melt flow rate value is 70g
If it exceeds / 10 minutes, the strength of the obtained core-sheath type composite continuous fiber B tends to decrease, and the strength of the laminated long-fiber nonwoven fabric tends to decrease. The spinning temperature at the time of obtaining the core-sheath type composite filament B by melt composite spinning is preferably such that the core component spinning temperature is about 230 to 270 ° C, particularly preferably about 240 to 260 ° C. Preferably, the spinning temperature of the sheath component is preferably about 220 to 265 ° C, particularly preferably 23 to 265 ° C.
The temperature is preferably set to about 0 to 255 ° C. If the spinning is carried out at a temperature higher than this temperature, the surface of the spinneret becomes liable to be stained, and if the operation is carried out for a long time, thread breakage occurs with time, making it difficult to obtain a uniform B layer. In addition, if the spinning is performed at a temperature lower than this temperature, it is difficult to perform stable melt spinning.

The layer A and the layer B are laminated to form a laminated web. As a method of forming a laminated web, a preformed A layer and a preformed B layer may be laminated, or a core-sheath type composite filament B may be accumulated on the preformed A layer to form a B layer. The layers may be formed, and the layer A and the layer B may be laminated to form a laminated web. Also, the previously formed B
The long fibers A may be accumulated on the layer to form the layer A, and the layer B and the layer A may be laminated to form a laminated web.

Next, the laminated web is pressed using an uneven roll. Specifically, it is carried out by introducing a laminated web between embossing rolls composed of an uneven roll and a smooth roll. Further, a laminated web may be introduced between embossing rolls composed of a pair of uneven rolls. In the present invention, at this time, the temperature of at least one concave-convex roll of the embossing roll is set to a constant temperature. That is, the melting point of the linear low-density polyethylene used for obtaining the long fiber A is 5
It is heated to a temperature lower by ~ 30 ° C. If the temperature of the concavo-convex roll is set lower than this temperature, the thermal fusion between the long fiber A and the core-sheath type composite long fiber B becomes insufficient, and the resulting laminated long-fiber nonwoven fabric is delaminated. And the surface of the laminated long-fiber nonwoven fabric is easily fuzzed, which is not preferable. Conversely, if the concavo-convex roll is set at a temperature higher than this temperature, the heat-bonded area between the long fiber A and the core-sheath type composite long fiber B becomes a film, and the flexibility of the laminated long-fiber nonwoven fabric becomes Is undesirably reduced. When the laminated web is pressed by the above-described method, heat fusion occurs in the area of the laminated web corresponding to the convex portion of the uneven roll.
Therefore, in certain areas arranged at intervals,
The long fiber A and the core-sheath type composite long fiber B are heat-fused. Then, a laminated long-fiber nonwoven fabric in which the layer A and the layer B are joined is obtained.

[0019]

【Example】

Example 1 A linear low-density polyethylene obtained by copolymerizing 5% by weight of octene-1 and 95% by weight of polyethylene was prepared. The density of this linear low density polyethylene is 0.937 g / c.
c, the melt index value is 35 g / 10 min,
Melting point was 125 ° C. This linear low-density polyethylene is melted and supplied to a spinneret having 200 holes and a spinning temperature of 235.
Melt spinning was performed at a temperature of 1.degree. C. and a single hole discharge rate of 1.20 g / min. Then, the long fiber A discharged from the spinning hole was taken out by using an air jet provided at a position 150 cm below the spinneret. The fineness of the long fiber A thus obtained was 2 denier. Next, at the exit of the air jet,
After the long fibers A were spread by the method of forced charging, they were accumulated on a running endless metal mesh to form an A layer. The basis weight of the layer A was 15 g / m ² .

Next, the linear low-density polyethylene used to obtain the long fiber A was mixed with a melt flow rate of 20 g /
A 10 minute polypropylene was prepared. Then, using a low-density linear polyethylene as a sheath component and polypropylene as a core component, melt composite spinning was performed with a composite spinneret having 200 holes.
The spinning conditions at this time are as follows. That is, the spinning temperature of the linear low-density polyethylene is 235 ° C., the spinning temperature of the polypropylene is 250 ° C., the composite ratio of the sheath component and the core component is sheath component: core component = 50: 50, The discharge rate is
1.25 g / min. The core-sheath type composite long fiber B discharged from the spinning hole as described above was taken out using an air jet provided at a position 180 cm below the spinneret. The fineness of the obtained core-sheath type composite continuous fiber B was 3.0 denier.
Thereafter, at the outlet of the air jet, the core-sheath type composite continuous fiber B is spread by a method of forced charging, and then the core-sheath type composite continuous fiber is placed on the A layer mounted on the traveling endless wire mesh. B
Were laminated to form a layer B, and a laminated web formed by laminating the layer A and the layer B was formed. The basis weight of the formed layer B was 15 g / m ² , and the basis weight of the laminated web was 30 g / m ² .

Thereafter, the laminated web was introduced into an embossing roll. This embossing roll is composed of a metal concavo-convex roll and a metal smooth roll. The temperature of the uneven roll was set at 115 ° C., and the linear pressure applied to the laminated web was 50 kg / cm. As described above, the long fiber A and the core-sheath type composite long fiber B were heat-sealed to obtain a laminated long-fiber nonwoven fabric. In addition, this heat fusion occurred at the portion of the laminated web corresponding to the convex portion of the concave-convex roll. Thus, heat fusion has been performed in certain spaced apart areas. The total area of this area was 12% with respect to the total area of the laminated long-fiber nonwoven fabric.

Various physical properties of the laminated long-fiber nonwoven fabric obtained as described above were measured, and the results were as follows. (1) Strength: 4.2 kg / 5 cm width (2) Elongation: 68% (3) Total hand: 23 g (4) Fluffiness: Good The methods for measuring the above various physical properties are as follows. (1) Strength: width 5 according to the strip method described in JIS-L-1096
The maximum tensile strength was measured using a test piece having a length of 0 mm and a length of 100 mm. Then, this maximum value was regarded as strong. (2) Elongation: The elongation of the test piece when exhibiting the above strength was measured. (3) Total hand: Measured with a slot width of 10 mm according to the handle ometer method described in JIS-L-1096. This total hand indicates the softness of the test piece. (4) Fluffiness: The surface of the test piece was rubbed using a friction tester type II conforming to the 45R method of JIS-L-1084. The conditions for this friction were as follows: the size of the test specimen was 14 cm x 5 cm, and a white cotton cloth for friction described in JIS-L-0823 was used as a friction element under a load of 200 g, and the distance between the test specimens 10 cm per minute. At a reciprocating speed of 30 times, 10
It rubbed back and forth 0 times. Then, the fluffing state on the surface of the test piece was visually determined. A case where there was little fluff was judged to be good, and a case where there was lots of fluff was judged to be bad.

Example 2 95% by weight of the linear low-density polyethylene used in Example 1
And 5% by weight of polypropylene having a melt flow rate of 20 g / 10 min. Were melted and spun using the spinneret used in Example 1. At this time, a long fiber A was obtained under the same conditions as in Example 1 except that the pressure of the air jet was changed. The fineness of the long fiber A was 1.6 denier. Then, a layer A having a basis weight of 15 g / m ² was obtained in the same manner as in Example 1. After that, a laminated long-fiber nonwoven fabric was obtained in the same manner as in Example 1.

The physical properties of the thus obtained laminated long-fiber nonwoven fabric were measured, and the results were as follows. Note Power: 4.5kg / 5cm width Elongation: 74% Total hand: 18g Fluffiness: good

Comparative Example 1 The linear low-density polyethylene used in Example 1 was spun under the same conditions as in Example 1 to obtain a long fiber A.
Then, the long fibers A were accumulated to form a web having a basis weight of 30 g / m ² . Using only this web, it was introduced into the embossing roll used in Example 1 and pressed under the same conditions as in Example 1 to obtain a long-fiber nonwoven fabric. Various physical properties of this long-fiber nonwoven fabric were as follows. Note Power: 2.2kg / 5cm width Elongation: 93% Total hand: 11g Fuzziness: Poor

Comparative Example 2 Using the mixture of linear low-density polyethylene and polypropylene used in Example 2 and spinning under the same conditions as in Example 2, a long fiber A was obtained. Then, the long fibers A were accumulated to form a web having a basis weight of 30 g / m ² . Using this web alone, the web was introduced into the embossing roll used in Example 2, and pressed under the same conditions as in Example 2 to obtain a long-fiber nonwoven fabric. Various physical properties of this long-fiber nonwoven fabric were as follows. Note Power: 2.5kg / 5cm width Elongation: 109% Total hand: 8g Fuzziness: Poor

Comparative Example 3 A core-sheath type composite continuous fiber B was obtained under the same conditions as in Example 1, and this was integrated to form a web having a basis weight of 30 g / m ² . Using only this web, it was introduced into the embossing roll used in Example 1 and pressed under the same conditions as in Example 1 to obtain a long-fiber nonwoven fabric. Various physical properties of this long-fiber nonwoven fabric were as follows. Note Strong: 6.3kg / 5cm width Elongation: 64% Total hand: 37g Fluffiness: good

As is clear from the results of the above Examples and Comparative Examples, the laminated long-fiber nonwoven fabrics according to the Examples were excellent in strength and flexibility, and had little fuzz. On the other hand, the nonwoven fabrics according to Comparative Examples 1 and 2 were excellent in flexibility, but low in strength and fuzzy. In Comparative Examples 1 and 2, when the temperature of the concavo-convex roll was increased to reduce fluffing, the flexibility of the obtained laminated nonwoven fabric was significantly reduced. Further, the nonwoven fabric according to Comparative Example 3 had high strength and little fluff, but was inferior in flexibility.

[0029]

As described above, the laminated long-fiber nonwoven fabric according to the present invention uses the low-density linear polyethylene composed of a fixed amount of a copolymer of ethylene and octene-1 to form the long fiber A. It has an A layer on which the long fibers A are accumulated. Therefore, the softness and softness due to the material of the linear low-density polyethylene can be imparted to the layer A. The layer A is laminated and bonded to a layer B in which core-sheath type composite long fibers B using polyethylene such as linear low-density polyethylene as a sheath component and polypropylene as a core component are accumulated. ing. The long fiber B in the B layer has a core component functioning as a skeletal fiber,
The layer B shows high strength. The bonding between the layer A and the layer B is performed by thermal fusion between the long fiber A and the core-sheath type composite long fiber B. Since the long fiber A and the sheath component of the core-sheath type composite long fiber B have a fixed relationship with respect to their melting points and softening temperatures, their heat fusion is strong. Therefore, the laminated long-fiber nonwoven fabric according to the present invention has an effect of exhibiting a very soft feeling and exhibiting high strength. Therefore, the laminated long-fiber nonwoven fabric according to the present invention can be suitably used as a surface material of a disposable diaper when the basis weight is low, and when the basis weight is high, a bag material, a carpet base cloth, and a filtration material are used. It can be suitably used as a cloth or the like.

──────────────────────────────────────────────────続 き Continuation of the front page (72) Inventor Nobuo Mimasa 23 Uji Kozakura, Uji-city, Kyoto, Japan Inside Central Research Laboratory of Unitika Ltd. (56) References JP-A-63-243324 (JP, A) JP-A-63- 227810 (JP, A) (58) Fields investigated (Int. Cl. ⁷ , DB name) D04H 3/00-3/16

Claims (6)

(57) [Claims] 1. A layer comprising a long fiber A mainly composed of a linear low-density polyethylene, and a B layer consisting of a core-sheath type composite long fiber B. In the laminated long-fiber nonwoven fabric in which the core-sheath type composite long fiber B is heat-fused and the layer A and the layer B are joined, the linear low-density polyethylene is 99 to 90% by weight. Is a copolymer of ethylene and 1 to 10% by weight of octene-1. The sheath component of the core-sheath type composite long fiber is a polyethylene which softens at least at the melting point of the linear low-density polyethylene. A laminated filament nonwoven fabric, wherein the core component is polypropylene. 2. The laminated long-fiber nonwoven fabric according to claim 1, wherein the fineness of the long fiber A and the core-sheath type composite long fiber B is 5 denier or less. 3. The laminated long-fiber nonwoven fabric according to claim 1, wherein the long fiber A is formed of linear low-density polyethylene of 80% by weight or more and polypropylene of 20% by weight or less. 4. The thermal fusion between the long fiber A and the core-sheath type composite long fiber B is performed in a fixed area disposed at intervals, and the total area of the area is equal to the lamination length. The laminated long-fiber nonwoven fabric according to claim 1, 2 or 3, which accounts for 4 to 40% of the total area of the fibrous nonwoven fabric. 5. 99% to 90% by weight of ethylene and 1% to 10% by weight
Having a melt index value of 20 to 80 g / 10 min and a density of 0.900 to 0.940.
long fiber A using g / cc linear low density polyethylene
And forming a layer A by accumulating the long fibers A, and using polyethylene which at least softens at the melting point of the linear low-density polyethylene as a sheath component, and having a melt flow rate of 10 to 70 g / 10 A core-sheath type composite long fiber B using polypropylene as a core component to obtain the core-sheath type composite long fiber B, forming a layer B,
Laminating the layers with each other to form a laminated web, and laminating the laminated web with a melting point of 5 to 3 from the melting point of the linear low density polyethylene.
2. The method for producing a laminated long-fiber nonwoven fabric according to claim 1, further comprising a step of pressing with an uneven roll heated to a temperature lower by 0 ° C. 6. The linear low-density polyethylene according to claim 5, wherein the polyethylene has a melt flow rate of 10 to 70 g /
6. The method for producing a laminated long-fiber nonwoven fabric according to claim 5, wherein long fibers A are obtained by mixing 10% or less of 20% by weight of polypropylene.