JPH09316798A - Plural layer granular thermally bondable bill - Google Patents

Abstract

PROBLEM TO BE SOLVED: To obtain a thermally bondable bill capable maintaining powerful bond strength without damaging air permeability and without impairing the surface gloss of the paper. SOLUTION: One side of a paper sheet substrate 1 is provided with a layer for preventing the transfer of a great number of parts of a thermoplastic resin A formed in an island shape in a discontinuous state to the paper sheet substrate 1. A thermally bondable resin layer B formed in a single or plural rock-like (granular) shape in a mutually discontinuous state is laid on the layer. Consequently, air permeability is not damaged, the surface gloss of the paper is not changed, the thermally bondable resin B is not soaked into the paper sheet substrate 1 and is transferred only to the side of a material to be bonded to enhance soaking adhesion. When the transfer preventing layer A is hydrophobic and the thermally bondable resin B is water-soluble, the paper sheet substrate after will not be released by adsorbed water, maintains strong adhesion but is readily peeled when water is sprayed on the side of the water-soluble thermally bondable resin.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a sticking paper which can be suitably used as a sticking paper such as wall paper, fusuma paper, shoji paper, and backing paper for calligraphy.

[0002]

BACKGROUND OF THE INVENTION The applicant of the present invention previously disclosed in Japanese Utility Model Publication No. 63-50320 a "thermal adhesive shoji paper" which can be easily replaced by heating and pressing with an iron, a trowel or the like. In Japanese Patent Publication No. 5-77800, a "heat-bonded paper sheet" is improved by using a steam iron so that a paper sheet material having a larger area than a heating surface such as wallpaper, fusuma paper, shoji paper, and backing paper of a calligraphy can be attached without wrinkles. Was disclosed.

Further, further, Japanese Patent Laid-Open No. 7-300575
Japanese Patent Laid-Open Publication No. 2004-242242 discloses that a heat-adhesive resin is transferred, scattered, sprayed or applied to the adhesive surface of a paper sheet substrate in a non-continuous state, and then the heat-adhesive resin is heated and melted to form a spherical or hemisphere of the heat-adhesive resin. A heat-bonded paper which is maintained in the form of islands is disclosed. Accordingly, particularly when the heat-adhesive paper is used for shoji paper, glossiness (shiny) due to melting of the resin layer as the heat-adhesive does not occur and it is not unsightly.

However, since the heat-adhesive resin is formed in an island shape, the heat-adhesive resin permeates into the paper sheet base material during reheating (at the time of pasting work), so that the amount of the welding resin on the adherend is reduced. Since it decreases, there is a drawback that the adhesive strength is weakened.

Therefore, the publication also discloses a structure in which a film layer for preventing transfer of the heat-adhesive resin is provided on one side, both sides or the middle of the paper sheet base material.

[0006]

However, in the structure having the film layer for preventing the transfer of the heat-adhesive resin, the air permeability is lost and the problem of dew condensation occurs on the surface of the paper sheet base material. Further, when the film layer is laminated on the surface, there is a problem that the original surface gloss of the paper is impaired.

The problem to be solved by the present invention is to maintain a strong adhesive force without impairing the air permeability and the surface gloss of the paper.

[0008]

SUMMARY OF THE INVENTION According to the present invention, a paper sheet base material is provided on one side with a layer for preventing transfer of a large number of discontinuous island-shaped thermal adhesive resins to the paper sheet base material. It is characterized in that a heat-adhesive resin layer formed in a so-called granular shape or a plurality of rock-like shapes which are discontinuous with each other is provided thereon.

As a result, the heat-adhesive resin does not permeate into the paper sheet base material, does not impair the air permeability, does not change the surface gloss of the paper even after thermal bonding, and transfers only to the adherend side, and permeates. It has the effect of strengthening the adhesion. When the transfer prevention layer is hydrophobic and the heat-adhesive resin is water-soluble, it does not peel off due to the moisture adsorbed on the paper sheet base material after sticking and maintains strong adhesion, but it is water-soluble heat-adhesive. If water is applied to the resin side by spraying or the like, there is also an effect that it is easily peeled off.

[0010]

BEST MODE FOR CARRYING OUT THE INVENTION
The "paper sheet material" disclosed in Japanese Patent Publication No. 77800 can be used, but a paper base material containing 5% to 100% hydrophobic fibers to improve dimensional stability against temperature changes and humidity changes. Alternatively, a non-woven fabric substrate is preferred.

As the hydrophobic fiber, one having good dimensional stability against heat at the heat-bonding working temperature is selected from the "hydrophobic heat-shrinkable fiber", "inorganic fiber" and "vinylon fiber" disclosed in the above publication. You just have to choose.

When forming a layer for preventing the transfer of the heat-adhesive resin in the form of a large number of islands in a non-continuous state, for example, in the case of applying to shoji paper, the resin directly adhering to the paper base is applied to the paper base by the paste dot method. After transfer to the material, the powder dot method is used to spread the powdery thermal adhesive resin on top of it, and the powder resin scattered other than on the paste dots is shaken off or removed by suction, and the paste dots ( Island) and powder resin (rock) are provided on it, dried by a heating and drying device, melted by heating and completed.

FIG. 1 is a schematic view showing an example of steps for realizing the process of forming the layer for preventing the transfer of the heat-adhesive resin into a large number of discontinuous islands.

The paper base material 1 passes between the drum 2 and the pressing roll 3 and is conveyed along the curved surface of the drum 2. At the upper end of the drum 2, a rotary screen 4 is provided in pressure contact with the drum 2. Inside the rotary screen 4, a paste supply device 5 and a squeegee 6 are arranged, and when the paper base material 1 passes between the drum 2 and the rotary screen 4, the resin A is applied to the paper base material by the paste dot method. It is transferred to the material 1. That is,
The resin A supplied from the paste supply device 5 is the squeegee 6
As a result, the surface of the paper base material 1 is applied through the mesh of the rotary screen 4, whereby the resin A for paste dots is transferred to the paper base material 1 in an island shape. FIG.
(A) shows that after processing by the paste dot method,
It is a schematic cross section which shows the adhesion state of resin A with respect to the paper base material 1. As can be seen from FIG. 2A, the resin A is transferred in a state where a part thereof penetrates into the paper base material 1.

The paper base material 1 that has passed between the drum 2 and the rotary screen 4 passes below the thermal adhesive resin spraying device 7. The heat-adhesive resin spraying device 7 includes a hopper 8 for accommodating the heat-adhesive resin B, and a supply roll 9 for cutting and supplying a predetermined amount of the heat-adhesive resin B in the hopper 8. The heat-bonding resin B is sprayed. FIG. 2B is a schematic cross-sectional view showing a sprayed state of the powdery thermal adhesive resin B on the paper base material 1 after passing through the thermal adhesive resin spraying device 7. As can be seen from FIG. 2 (b),
The powdery heat-adhesive resin B is sprayed directly on the surface of the paper base material 1 as well as on the island-shaped resin A.

The paper base material 1 that has passed through the heat-adhesive resin spraying device 7 passes through a heat-adhesive resin shake-off device 10. The heat-bonding resin shake-off device 10 includes two rolls 11A and 11B arranged substantially vertically and these rolls 1
Thermal adhesive resin recovery device 1 arranged below 1A and 11B
2 is provided. The powdery heat-adhesive resin B directly spread on the surface of the paper base material 1 is placed on the paper base material 1 by gravity, while the powdery heat-adhesion resin B on the island-shaped resin A is adhered. Since the resin B adheres to the resin A due to the adhesive force of the resin A, when the paper base material 1 passes vertically through the heat-bonding resin recovery device 12, the powder-like heat-bonding on the paper base material 1 is performed. The resin B is shaken off from the paper base material 1 and falls by gravity onto the thermal adhesive resin recovery device 12. When the paper base material 1 passes vertically through the heat-adhesive resin recovery device 12, the vicinity of the surface of the paper base material 1 is evacuated by vacuum to suck the powdery heat-adhesive resin B on the paper base material 1. You may do it. FIG. 2 (c)
It is a schematic cross section which shows the state of the powdery heat-bonding resin B after passing the heat-bonding resin shake-off device 10. FIG.
As can be seen from (c), the powdery heat-bonding resin B adheres only onto the island-shaped resin A.

The paper substrate 1 that has passed through the heat-bonding resin shake-off device 10 is conveyed to the heat-drying device 13 by a guide means (not shown) and is heated and dried. As a result, the powdery thermal adhesive resin B is welded to the surface of the island-shaped resin A.

The paper base material 1 after heating and drying is cooled by the cooling device 14 to complete the double-grain heat-bonding paper of the present invention.

As the above-mentioned paste dot resin, a heat-bonding resin which is usually used, for example, Japanese Patent Publication No. 5-7.
The "heat-sensitive adhesive" disclosed in Japanese Patent No. 7800 is used, but it is preferable that the hydrophobic LDPE has a property that does not affect the adhesive force and the texture that are not affected by the change of water content.
A system, EVA system, modified EVA system, polyester system, polyamide system, modified PE system, ionomer system and the like can be preferably used, but water-soluble modified PVA system and the like have an adhesive force and a texture depending on a change in water content. It is not preferable because it is affected. From the melting point of 60 to 170 ° C., the kind and melting point may be selected according to the application. In addition to the heat-adhesive resin, a thermoplastic or thermosetting urethane resin or its derivative, an acrylic resin or its derivative, or 2
It may be one kind or a composite of three kinds. Further, 1 to 10% of ceramic powder such as TiO ₂ may be mixed in order to eliminate the gloss of the resin. Further, a pigment may be mixed in order to match the color of the paper base material. Adhesiveness to the paper base material is good in selection, but it has a lower melt flow rate (MFR) and a melting point (M
Higher P) is preferred. Further, in order to improve the adhesiveness of the powder dot (rock) to the heat-adhesive resin, the same type of resin may be mixed.

Further, since the powder dot resin is a resin for thermally adhering to the screen of the shoji screen, among the "heat-adhesive resins", one having good adhesiveness to the island-shaped resin provided by the paste dots is used. You just have to choose. Furthermore, when a hydrophobic resin is used as the paste dot resin and the hygroscopic (water) property of the paper base material is separated from the heat-adhesive resin, a water-soluble modified PVA system can be used as the powder dot resin. In this case, when sticking with an iron and peeling it off, water can be sprayed from the crosspiece side of the shoji screen so that the adhesive resin does not melt and the crosspiece can be removed cleanly and easily.

[0021]

Example: Pulp 65%, rayon 25%, vinylon 5
% And a binder of 5%, the resin paste (1) and the powder resin (2) shown in the respective examples were applied and bonded under the conditions shown in (3).

Example 1 (1) Resin paste used Permarin KZ-17A: 40 parts (manufactured by Sanyo Chemical Industries) Polyamide resin (Note 1): 27 parts Water: 30 parts Titanium: 3 parts (Note 1) Daicel Huls Company Made "Vestamelt 171
-P1 "Melting point 119 ° C MFR 4g / 10mi
n (160 ° C) Galvano screen (2
2.5 p / inch φ0.36 mm) to form islands of paste dots.

(2) Powder resin Polyamide-based Daicel Hüls "Vestamelt 7"
30-P816 "Melting point 98 ° C MFR 100g
/ 10 min (160 ° C.) The above resin was sprinkled on the paste dots to shake off the powder resin falling on a portion other than the paste dots to form a state where rocks were placed on the islands.

(3) Heat drying (the above-mentioned sheet was heated to 140 °
C, 60 seconds), then iron a wooden frame for household use (160 ° C)
However, the relatively large island-shaped resin did not soak into the paper sheet material, and the heat-adhesive resin reliably melted and transferred to the wooden frame to obtain good adhesive strength.

Example 2 (1) Resin paste used Urethane emulsion resin (manufactured by Dainippon Ink and Chemicals, RYUDYE-WBINDER-WD-285) The above paste was applied to shoji paper using a galvano screen (22.
5 p / inch φ 0.4 mm) to form paste dots.

(2) Powder resin PVA-based water-soluble heat-adhesive resin (Unitika Resin UMR-10MD manufactured by Unitika) Sprinkle the above resin on the paste dots formed in (1), and shake off the powder that falls outside the paste dots. To form a powder rock on top of the paste dot island.

(3) 14 sheets of the above-mentioned sheet processed in (2)
After heating and drying at 0 ° C for 60 seconds, iron the household iron (16
A strong adhesive force was obtained when adhered at 0 ° C. afterwards,
Water was sprayed on the shoji paper, but the adhesive strength did not decrease. Water was sprayed from the side of the wooden frame, and after waiting for water to seep in (1 minute later), when peeling, the sheet was peeled off cleanly and easily from the wooden frame.

In both Examples 1 and 2, since the resin is provided in an island shape on the paper sheet base material, the original air permeability of the paper is not impaired, and the resin surface is melted by being heated once during processing. Since it is mirror-like, the surface shape of the resin does not change due to reheating, so the gloss of the paper does not change.

Further, in the case of the heat-bonding interlining used for clothing, heating can be performed from both sides or the adherend side, but shoji paper cannot be heated from the wooden frame side (adhesion side) and the paper cannot be heated. It is for this reason that the multi-layered granular heat-adhesive paper of the present invention having a layer for preventing transfer to the paper sheet base material is effective as a means for enabling strong adhesion because it is heated only from the side.

[0030]

EFFECTS OF THE INVENTION The multi-layered granular thermal bonding paper of the present invention has the following effects.

(1) Despite the extremely small amount of resin as compared with the film-laminated product of the heat-adhesive resin, even if the paper is wet, a strong adhesive force close to that of the laminated product can be obtained.
Moreover, since the gloss of the paper does not change, the natural gloss is maintained.

(2) Since air permeability is maintained, there is no risk of dew condensation after application.

(3) If a water-soluble PVA type is used for the "heat-adhesive resin", the wooden frame can be easily peeled off without being soiled when water is added from the wooden frame side.

[Brief description of drawings]

FIG. 1 is a schematic view showing an example of steps for realizing a process of forming a layer for preventing transfer of a heat-adhesive resin into a large number of islands in a discontinuous state.

FIG. 2 is a schematic cross-sectional view showing how a powdery heat-adhesive resin is attached to a paper base material and a paste dot resin.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Paper base material, 2 ... Drum, 3 ... Press roll, 4 ... Rotary screen, 5 ... Paste supply device, 6 ... Squeegee, 7 ... Thermal adhesive resin spraying device, 8 ... Hopper, 9 ... Supply roll, 10 ... Heat Adhesive resin shake-off device, 11A, 11
B ... Roll, 12 ... Thermal adhesive resin recovery device, 13 ... Heat drying device 14 ... Cooling device A ... Paste dot resin, B ...
Powdered heat adhesive resin

─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. ⁶ Identification number Internal reference number FI Technical indication location C09J 5/10 JGV C09J 5/10 JGV 7/04 JKN 7/04 JKN (72) Inventor Yasunobu Nakamura 229 Tsue, Ome, Yame city, Fukuoka prefecture (72) Inventor Mitsuaki Nojima 3-16-16, Uedo-muro, Takatsuki-shi, Osaka E02-202

Claims (1)

[Claims] 1. A heat-bonding paper comprising a paper sheet base material on one side of which a plurality of island-like heat-bonding resins are provided in a non-continuous state. A multi-layered granular heat-adhesive paper, comprising a layer for preventing transfer of the heat-adhesive resin in an island shape, and a heat-adhesive resin layer provided on the layer for preventing transfer.