JPH05263372A - Sheet material and its production - Google Patents

Abstract

PURPOSE:To provide a sheet, material giving appearance of stereoscopic pattern, thus suitable for facing floor tiles, wall tiles, or furniture, all of which have full of variety. CONSTITUTION:The objective sheet material having such structure that a base material 1 is laminated with a facing material which is made up of (1) a vinyl chloride-based resin film 5 and (2) a fiber-incorporated transparent vinyl chloride- based resin layer 3 where individual constituent fibers are nonlinearly, randomly crossed mutually in a separated, independent manner, and, besides, nonwoven fabric-like filamentous fibers 4 with a single fiber fineness of 10-50 denier and >=75% in mean transmittance and 300-700 in formation index are dispersed.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a floor tile, a wall tile, a sheet material used for the surface mounting of walls, furniture and the like, and a method for producing the same.

[0002]

2. Description of the Related Art Conventionally, ceramic tiles have been widely used as general floor tiles and wall tiles. However, this ceramic tile has a high manufacturing cost, a high construction cost, and a long construction period. At present, vinyl chloride resin tiles are widely used because of the decrease in skilled workers.

However, most of the patterns and designs on the surface of these tiles are gravure roll printing methods.
For this reason, it is difficult to express a color pattern with a three-dimensional depth. In addition, in recent years, with the era of diversification and individualization, the demand for high-quality and highly original products is inevitably increasing, and inevitably small-lot production is inevitable.However, the printing method makes it difficult to handle small-lot production, and high cost Conventional resin tiles are not able to meet the needs of these markets.

[0004]

As a solution to this problem, a fiber sheet containing heat-sealing fibers containing a vinyl chloride-based resin as a main component is laminated on a vinyl chloride-based resin film to be fused and integrated. Has proposed a sheet material having various appearances and three-dimensional effects (Japanese Patent Laid-Open No. 2-153729).

In addition to the above-mentioned characteristics, this sheet material is also excellent in water resistance and suitable for outdoor use, and is suitable as a floor tile, a wall tile, etc.
Recently, the trend toward higher grades is becoming more sophisticated, and more sophisticated appearances and three-dimensional views tend to be required. To meet these higher market needs, it is not enough to simply form a fiber pattern on the sheet surface. The major point is what kind of fiber sheet is used to form what kind of pattern. The present invention aims to solve such problems.

[0006]

Means for Solving the Problems The gist of the present invention is that non-linear and random crossovers of individual constituent fibers are separated and independent on a base material, and the average transmittance is 75%.
Above, formation index is formed in the range of 300-700 1
A sheet characterized in that a non-woven filament fiber having a fineness of 0 to 50 denier is fused and integrated with a vinyl chloride resin film in a state of being embedded in a transparent vinyl chloride resin layer. Material and its manufacturing method, that is, a vinyl chloride resin film on a substrate, and 30 to 95% by weight of a heat-sealing fiber containing a vinyl chloride resin as a main component.
A fiber paper sheet containing, the individual constituent fibers are separated and independent, and are non-linearly and randomly crossed. Further, the average transmittance is 75% or more, and the formation index is formed in the range of 300 to 700. A sheet material comprising a nonwoven fabric filament fiber having a fineness of 10 to 50 denier and a melting point higher than that of the heat fusion fiber, and a vinyl chloride resin film, which are sequentially laminated and fused together. It is in the manufacturing method.

The present invention will be described in detail below with reference to the drawings. 1 and 2 are cross-sectional views schematically showing an example of the sheet material of the present invention, in which 1 is a base material, 2 is a vinyl chloride resin film, and a transparent resin layer 3 is fused and integrated. Has been done. Nonwoven fabric filament fibers 4 are embedded in the resin layer 3, and the surface thereof is covered with a vinyl chloride resin film 5 in a fusion-bonded manner. Figure 2
FIG. 1 shows a state in which short fibers 6 are further dispersed and mixed in the transparent resin layer 3.

Various materials are selected and used as the base material 1 according to the use of the sheet material. If a vinyl chloride resin sheet is used, a vinyl chloride resin film 2 is used.
It is effective in that it does not require a special adhesive or a bonding step because it can be easily bonded to and can be bonded at the same time during the fusion and integration process. When used as a rug, it is possible to obtain a stable feeling by using a material mixed with a heavy material such as calcium carbonate.

The vinyl chloride-based resin film 2 is intended to give a deep appearance to the sheet material and improve the adhesiveness to the substrate 1 by being fused and integrated with the resin layer 3. is there. In this case, if the colored vinyl chloride resin film 2 is used, it is possible to form a deeper pattern by combining with the fibers present in the transparent resin layer 3. Moreover, when a pattern is printed on the surface of the film 2 separately from the pigment kneading coloring,
The design effect becomes even more effective.

In this case, it is preferable that the colored vinyl chloride resin film 2 has a contrast with the colored fibers present in the resin layer 3,
When the difference in shade and hue is small, it becomes difficult to distinguish the colored fibers existing in the resin layer 3, and the stereoscopic effect is poor.

The resin layer 3 is formed by melting and thermally adhering a heat-bonding fiber containing a vinyl chloride resin as a main component to a vinyl chloride resin film, and mainly comprises a vinyl chloride resin. Therefore, it has a transparent shape, and the filament fiber 4 formed in a non-woven fabric shape is embedded inside the transparent resin layer 3.

In the present invention, the form of the non-woven filament fiber 4 is an important constituent element, and the individual fibers constituting the non-woven filament fiber 4 are separated and independent and are non-linear. Moreover, it is transparent because the fibers are randomly crossed, the fineness of the constituent fibers is in the range of 10 to 50 denier, the average transmittance is 75% or more, and the formation index is in the range of 300 to 700. It has a deep three-dimensional pattern with a three-dimensional fiber pattern in the ground.

In this case, when the average transmittance is 75% or less, the transparency becomes poor, and the vinyl chloride resin film 2
And other colored mixed fibers and non-woven filament fiber 4
It is difficult to provide contrast with and a deep pattern cannot be obtained.

When the formation index is 300 or less, the individual fibers constituting the non-woven filament fiber 4 have an excessively uniform distribution, and the effect as a pattern becomes poor even when the permeability is large. .. Conversely, formation index is 70
When it exceeds 0, the individual fibers constituting the non-woven filament fiber 4 are excessively aggregated, and the balance between the fiber portion and the transmission portion is lost, and the effect as a pattern is also poor.

Regarding the fineness, if the fineness used is in the range of 10 to 50 denier, the contrast as a pattern becomes poor if it becomes too thin, and the formation index decreases if it becomes too thick, and the effect as a pattern also becomes poor. ..

The average transmittance in the present invention means that the light received from the pixel is measured by shining light from the lower part of the sample, dividing the transmitted image into 128 × 128 pixels by a CCD camera and measuring the intensity of the light received by each pixel. Is an average of the transmittances calculated from the strengths of, and is measured by the following method.

[0017]

[Formula 1]

Further, the formation index in the present invention is obtained by multiplying the coefficient of variation (standard deviation divided by the average absorbency) representing the unevenness of formation by 10 times, and represents the size of the unevenness per unit basis weight. is there.

[0019]

[Formula 2]

The fiber material is not particularly limited as long as it has a melting point temperature higher than that of the heat-sealing fiber containing vinyl chloride resin as a main component and the vinyl chloride resin film.

Short fibers 6 may be mixed in the resin layer 3 if necessary. In this case, it is preferable to keep a small amount of the short fibers 6 in a dispersed state from the viewpoint of the contrast with the non-woven filament fiber 4, and if colored short fibers are used, the appearance can be further varied.

The vinyl chloride resin film 5 forming the outermost layer is for protecting the resin layer 3.
In addition to protecting the sheet material, it is necessary to have transparency so that the pattern of the resin layer 3 can be seen through. In the present invention, since the vinyl chloride resin is used as the composition, the adhesiveness with the resin layer 3 is good, and since the composition is the same as that of the resin layer 3, a uniform transparent appearance is obtained. The thickness of the film may be selected and used as necessary, but a soft film is preferable from the viewpoint of taking advantage of the uneven shape of the surface formed by the internal fibers of the resin layer 3.

Next, the manufacturing method of the present invention will be described. Laminate a vinyl chloride resin film on any substrate,
A fiber paper sheet containing heat-sealing fibers is laminated thereon.
In this case, as the heat-sealing fiber, one having a vinyl chloride resin as a main component is used. The content of the heat-sealing fiber needs to be 30% by weight or more, and if it is less than 30% by weight, the adhesiveness with the vinyl chloride resin films 2 and 5 becomes insufficient, and the nonwoven fabric-like filament fiber described later. The embedding of No. 4 is insufficient and a deep appearance pattern cannot be obtained. Further, if it is 95% by weight or more, it becomes difficult to fabricate fibers.

When forming the fiber paper sheet, short fibers may be mixed in an amount of 2 to 15% by weight. As the short fiber to be mixed and mixed, any natural fiber, synthetic fiber or the like may be used as long as it has a melting point higher than that of the vinyl chloride resin which is a composition component of the heat fusion fiber. The fiber length and fineness are not particularly limited, but thick fibers are preferable from the viewpoint of forming a ground pattern of short fibers.

Nonwoven filament fiber 4 is further laminated on the above-mentioned fiber paper sheet. As described above, the filament fiber nonwoven fabric 4 is non-linear and randomly intersects with the individual fibers constituting the filament fiber nonwoven fabric 4 being separated and independent, and further, the average transmittance is 75%. As described above, the formation index is formed in the range of 300 to 700, and further has a fineness of 5 to 30 denier,
It has a melting point higher than that of the heat fusion fiber. Such a non-woven fabric can be easily obtained by using, for example, a filament non-woven fabric manufactured by Akzo Co., Ltd. in the Netherlands (highly labeled “Colvac”).

Thus, the non-woven filament fiber 4
The individual fibers constituting the are independent and non-linearly and randomly crossed, the fineness of the constituent fibers is in the range of 10 to 50 denier, and the average transmittance is 75. % Or more and the formation index is in the range of 300 to 700, a deep three-dimensional pattern having a three-dimensional fiber pattern in the transparent ground portion can be obtained.

As described above, a vinyl chloride resin film 2, a fiber sheet 3 and a filament fiber non-woven fabric 4 are laminated on the base material 1 and, if necessary, a transparent vinyl chloride resin serving as a protective layer on the top. The resin film 5 is laminated. The vinyl chloride resin film 5 may be partially or entirely colored in a range not impairing transparency.

In this way, the laminated sheet is heated and pressure-bonded to melt the heat-fusible fiber which is the main component of the fiber sheet, and the upper and lower vinyl chloride resin films 2 with the non-woven filament fiber 4 interposed therebetween. , 5 and fused together.

[0029]

【Example】

(Example 1) A vinyl chloride sheet containing 250 parts by weight of calcium carbonate per 100 parts by weight of vinyl chloride as a base material, on which a lightly colored vinyl chloride resin film,
Wet non-woven fabric prepared by a paper-making method using 80% by weight of heat-sealing fibers obtained from a copolymer of 85% by weight of vinyl chloride and 15% by weight of vinyl acetate and 20% by weight of a binder such as polyvinyl alcohol. , Polyester and nylon-6 are respectively used for the core and the sheath, and the polyester / nylon composite fiber (15d monofilament fiber) obtained by the composite spinning and drawing is supplied in a randomly swirling state and collected on the conveyor belt. Nonwoven fabric filament fibers having an average transmittance of 85% and a formation index of 450 formed into a sheet with a basis weight of 30 g / m ² were sequentially laminated, and a soft vinyl chloride resin film was laminated thereon, and the temperature was raised to 140 ° C. After heating and thermocompression bonding at a pressure of 15 kg / cm ² for 3 minutes,
It was left to cool.

As a result, the entire sheet is fused and integrated and strongly bonded, and the transparent resin layer formed by melting the heat-sealing fibers has a filament fiber having an average transmittance of 85% and a formation index of 450. Thus, a sheet material having a depth and a three-dimensional effect, in which the presence of a sheet was present, was obtained. The formation rate tester “FMI-1000A” was used to measure the average transmittance and formation index.
(Manufactured by Nomura Shoji Co., Ltd.) was carried out by the method described above.

(Example 2) When a wet non-woven fabric is produced by a papermaking method, a lightly colored hard vinyl chloride resin film and acrylic short fibers (25 d) colored in three different colors
5% by weight of (5 to 50 mm random cut) was mixed. Other than that was manufactured in the same manner as in Example 1, and as a result, a sheet material having filament fibers and colored short fibers in the transparent resin layer and having a high-grade three-dimensional appearance due to the contrast thereof was obtained.

[0032]

The sheet material of the present invention is excellent in transparency because the resin layer in the middle is formed by fusing vinyl chloride-based heat-sealing fibers, and this resin layer is also excellent. The film sheets located on both sides of the film also have a deeper transparency because they have a vinyl chloride composition.

In particular, in the resin layer of the present invention, the non-woven filament fiber is embedded in the resin layer in a non-linear and randomly intersecting state in which the individual constituent fibers are separated and independent. It has a three-dimensional shape and has an appearance with a deep pattern in which fibers are three-dimensionally present in the transparent ground portion. At that time, since the non-woven filament fiber has a specific transmittance and formation index, a pattern portion having a good balance between the base portion made of a transparent resin and the non-woven filament fiber is formed.

Further, if a colored vinyl chloride resin film is used, it is possible to form a deeper pattern by combining with the fibers present in the transparent resin layer. Further, if a small amount of colored short fibers are dispersed and contained in the transparent resin layer, a higher grade three-dimensional pattern can be obtained in combination with the presence of the non-woven filament fiber.

[Brief description of drawings]

FIG. 1 is a sectional view schematically showing an example of a sheet material of the present invention.

FIG. 2 is a cross-sectional view schematically showing another example of the sheet material of the present invention.

[Explanation of symbols]

 1 Base Material 2 Vinyl Chloride Resin Film 3 Resin Layer 4 Nonwoven Fabric Filament Fiber 5 Vinyl Chloride Resin Film 6 Short Fiber

Claims (4)

[Claims] 1. A base material in which individual constituent fibers are separated and independent and are non-linearly and randomly crossed. Further, the average transmittance is 75% or more, and the formation index is 300 to 700.
The non-woven filament fiber having a fineness of 10 to 50 denier formed in the range of 10 is fused and integrated with the vinyl chloride resin film while being embedded in the transparent vinyl chloride resin layer. A sheet material characterized in that 2. The sheet material according to claim 1, wherein a small amount of short fibers having a hue different from that of the non-woven filament fiber is dispersed and mixed in the resin layer. 3. A vinyl chloride resin film, a heat-sealing fiber 30 containing a vinyl chloride resin as a main component on a base material.
A fiber paper sheet containing up to 95% by weight, the individual constituent fibers are separated and independent, and are non-linearly and randomly crossed. Further, the average transmittance is 75% or more, and the formation index is 30.
A non-woven filament fiber having a melting point higher than that of the heat fusion fiber having a fineness of 10 to 50 denier formed in the range of 0 to 700, and a vinyl chloride resin film are sequentially laminated and fused and integrated. A method for producing a sheet material, comprising: 4. A fiber paper sheet containing 30 to 95% by weight of a heat-sealing fiber containing a vinyl chloride resin as a main component, and short fibers having a melting point higher than that of the heat-sealing fiber and having different hues. The method for producing a sheet material according to claim 3, wherein