KR20130085757A - Printed lamination structure - Google Patents

Abstract

PURPOSE: A printing lamination sheet is provided to give interlayer adhesion strength between printing layer and polyurethane layer. CONSTITUTION: A printing lamination sheet comprises a cloth; multiple layers in which an ink layer is coated on polyurethane layer; and multiple layers which are formed on a cloth with an ink in ink layer having a solvent for polyurethane. Polyurethane layers (30,70) are located at a cloth side based on an ink layer (50). Polyurethane layer is located at an opposite side of a cloth based on an ink layer. A cloth is made of polyurethane at the side of facing with an ink layer. Polyurethane adhesive layer is included between a cloth and an ink layer.

Description

Printed laminated sheet {PRINTED LAMINATION STRUCTURE}

The present disclosure relates to a printed laminated sheet as a whole, and more particularly to a printed laminated sheet having enhanced adhesive strength.

Herein, the background art relating to the present disclosure is provided, and these are not necessarily meant to be known arts.

Synthetic leather sheets, such as Nike shoes, are used by applying a polyurethane layer to a nonwoven or fabric. For color or image printing on such synthetic leather sheets, several methods have been proposed, in which a printing layer is formed on a separate polyurethane layer, and then the polyurethane layer on which the printing layer is formed is combined with the polyurethane layer of the synthetic leather sheet. It is becoming.

However, in the absence of a print layer, the polyurethane layer separate from the synthetic leather sheet side polyurethane layer, which had exhibited commercially viable adhesive strength (e.g. 4.5 kg / cm), was due to the presence of heterogeneous print layers (primarily dyes are used). It will show extraordinary adhesive strength.

1 is a view showing an example of a printing laminated sheet having a conventional printing layer, the upper photo shows a printing laminated sheet 100 provided with a printing layer. The printed laminated sheet 100 was made by laminating a separate polyurethane layer printed with a printed layer on a synthetic leather sheet having a polyurethane layer. The Nike mark 101 was attached to it using polyurethane high frequency bonding (the adhesive strength is very high because the separate polyurethane layer and the Nike mark 101 are bonded between polyurethanes without a printing layer). The middle photograph shows the state when the Nike mark 101 is torn off. It can be seen that the polyurethane layer 100a of the synthetic leather sheet is exposed, and the periphery where the Nike mark 101 has fallen is tolerated. The lower photo shows the backside 101a of the Nike mark 101 torn off. Ink remains on the back surface 101a, but ink remains on the polyurethane layer 100a. This means that the interface between the polyurethane layer 100a and the separate polyurethane layer has been separated. Through this it can be seen that the adhesive strength of the polyurethane layer 100a and the separate polyurethane layer is not high.

To help understand the present disclosure, first, the results of the present disclosure will be described.

FIG. 2 is a view showing an example of a printed laminated sheet according to the present disclosure, in which a Nike mark 21 is attached to a printed laminated sheet 20 similar to FIG. 1 by using polyurethane high frequency bonding (top photo; It is torn, but not for any deception, and is sufficient for explanation of the invention (also in the upper photo of Fig. 1), and using a knife to cut the Nike mark 21 (with the printing laminated sheet 100 of Fig. 1). Otherwise, the Nike mark 21 could not be removed by hand, and the Nike mark 21 was first incised with a knife.) The Nike mark 21 was removed (middle photograph). After tearing, it can be seen that the polyurethane layer 20a on the synthetic leather sheet side without ink is exposed. All of the ink is attached to the rear face 21a of the Nike mark 21 (lower photograph). This is because in the case of the present disclosure, the adhesive strength is strong, and the interface between the polyurethane layer 20a of the synthetic leather sheet and the separate polyurethane layer is not separated, but the bonding between them is strong so that the polyurethane of the synthetic leather sheet ( It means that the surface of 20a) is torn. 4.6, 5, 0, 4.7 shown in the picture is the adhesive strength.

This will be described later in the Specification for Implementation of the Invention.

SUMMARY OF THE INVENTION Herein, a general summary of the present disclosure is provided, which should not be construed as limiting the scope of the present disclosure. of its features).

According to one aspect of the present disclosure, according to one aspect of the present disclosure; And a composite layer coated with an ink layer on the polyurethane layer, the composite layer being formed on a fabric and having an ink in which the ink of the ink layer dissolves the polyurethane. .

This will be described later in the Specification for Implementation of the Invention.

1 is a view showing an example of a printing laminated sheet having a conventional printing layer,
2 is a view showing an example of a printing laminated sheet according to the present disclosure,
3 is a view showing another example of a printing laminated sheet according to the present disclosure,
4 is a view showing another example of a printing laminated sheet according to the present disclosure,
5 is a view showing another example of a printing laminated sheet according to the present disclosure,
6 is a view showing an example of a method of manufacturing a printing laminated sheet shown in FIG.
7 is a table of the effect test result of the printed laminated sheet prepared according to the present disclosure.

The present disclosure will now be described in detail with reference to the accompanying drawing (s).

3 is a view showing another example of a printed laminated sheet according to the present disclosure, the printed laminated sheet is a non-woven fabric or fabric 10, polyurethane layer 30, polyurethane adhesive layer 40, ink layer ( 50), polyurethane skin layer 60 and polyurethane layer 70. In this example, the fabric 10 and the polyurethane layer 30 correspond to conventional synthetic leather sheets, and the ink layer 50 and the polyurethane layer 70 form a composite layer. Preferably, the polyurethane adhesive layer 40 and the polyurethane skin layer 60 are further provided. As shown in FIG. 4, the polyurethane adhesive layer 40 may be located directly below the polyurethane layer 70, and may satisfy the adhesive strength required by only the polyurethane layer 30 and / or the polyurethane skin layer 60. Alternatively, the polyurethane layer 30 and / or the polyurethane skin layer 60 itself may be omitted if they have an adhesive component. Polyurethane is a polyurethane for synthetic leather.

4 is a view showing another example of a printing laminated sheet according to the present disclosure, the printing laminated sheet is a fabric 10, polyurethane layer 30, ink layer 50, polyurethane skin layer 60, polyurethane An adhesive layer 40 and a polyurethane layer 70 are provided.

The present disclosure is particularly characterized by the ink layer 50. The ink layer 50 itself melts the polyurethanes constituting the polyurethane layer 30, the polyurethane adhesive layer 40, the polyurethane skin layer 60, and the polyurethane layer 70 to form the ink and the corresponding polyurethane. Solvents to enhance adhesion. Such solvents can be made, for example, by mixing one or a mixture of solvents such as MEK, PMP, ANON, DMF and the like. As ink, pigment ink which is insoluble in water, oil, etc. is used, not dye ink which is dissolved in water, oil, or dye. The ink layer 50 is a solvent-based ink, which is directly applied to the polyurethane and directly binds to the applied polyurethane. This is distinguished from offset printing, gravure printing, sublimation transfer, and the like, which are conventionally used. A digital printer (such as an inkjet printer) is used for this application. Larger particles of the ink inhibit the adhesion between the polyurethanes, and therefore have a particle size of preferably 2 μm or less, more preferably 1 μm or less. This particle size is not unreasonable for use as ink in a digital printer, and from the standpoint of the digital printer, therefore, the particle size of the ink according to the present disclosure must be used in the digital printer because small particles that can be sprayed from the ink head are used. It may be said to have a printable particle size. For example, an ink may contain particles, such as blue or red, of 1 μm or less, and may be used alone or in a mixture of materials such as Propylene Glycol, 2-Pyrrolidione, Polyurethane alone, or a copolymer as a vehicle. It can be made by using, in one or a mixture of solvents such as MEK, PMP, ANON, DMF, etc. in the range of 10% to 300% of the solid content.

Preferably, the polyurethane skin layer 60 is composed of polyurethane which dissolves better with the solvent of the ink than the polyurethane layer 30 or the polyurethane layer 70, so as to improve the adhesive strength between the ink and the polyurethane. Used. In addition, by introducing the polyurethane skin layer 60, it is possible to adjust the physical properties of the polyurethane layer 70 according to this function for protecting the ink layer 50, which is one of the functions of the polyurethane layer 70 to form the outer layer. do. For example, the molecular weight of the polyurethane layer 70 may be formed of a polymer urethane of about 150,000, and the molecular weight of the polyurethane skin layer 60 may be formed of 50,000 to 100,000, and a polyurethane resin may be coated by coating a weak durable polyester resin. It is also possible to form the skin layer 60. As shown in FIG. 5, even when the ink layer 50 is applied to the polyurethane layer 30, the polyurethane skin layer 60 may be introduced on the same principle. However, the function of the polyurethane layer 30 is different in that it is the formation of a synthetic leather sheet.

5 is a view showing another example of a printed laminated sheet according to the present disclosure, wherein the printed laminated sheet includes a fabric 10, a polyurethane layer 30, a polyurethane skin layer 60, and an ink layer 50. . In this case, the fabric 10 and the polyurethane layer 30 constitute a synthetic leather sheet, while the polyurethane layer 30 and the ink layer 50 constitute a composite layer. Preferably, the polyurethane skin layer 60 is further provided. Since the ink layer 50 is directly applied to the polyurethane layer 30, the polyurethane adhesive layer 40 and the polyurethane layer 70 are not provided separately.

FIG. 6 is a view illustrating an example of a method of manufacturing the printing laminate sheet shown in FIG. 4.

First, the polyurethane layer 30 is formed on the fabric 10 to prepare a synthetic leather sheet. The polyurethane layer 30 is made by conventional wet processing and dry processing.

<Wet processing method> It is composed as shown in the table below, and the fabric used is non-woven fabric, Tricot, or Neat fabric. Main coating coagulation bath (water + DMF)-rinse-dry. Products that go through this process are called wet products or wet semi-finished products (after dry processing).

<Dry processing method> It is composed as the table below, and the procedure is' RP paper-Skin (3) coating-Drying-Bind (4) coating-(semi-drying)-Laim (adhesive; fabric or wet semi-finished product)-Aging- RP paper peeling '.

The polyurethane layer 30 collectively refers to both wet and dry dry layers which are processed at the same time as wet or dry after wet. In this way, a conventional polyurethane synthetic leather sheet is produced. Although one example has been given above, the formation of such polyurethane layer 30 is conventional to those skilled in the art of footwear, artificial leather. It is common to form the polyurethane layer 30 through the wet processing method after the wet processing method on the fabric 10.

Next, the process of forming a composite layer is demonstrated.

First, prepare RP paper 80 (release paper, release paper), and then form a polyurethane layer 70 of the thickness 0.1um ~ 40um on the RP paper 80 in the same manner as the above dry processing method. Since the polyurethane layer 70 is bonded to the layer by the dry processing method in the polyurethane layer 30, it is preferable to have the same or similar physical properties. Next, the polyurethane skin layer 60 is formed through application by a digital printer, and then the ink layer 50 is applied through digital printing by changing the digital printer or ink head, and the hot-melt polyurethane film already processed thereon is applied thereon. Using to form a polyurethane adhesive layer 40 of 0.1um ~ 40um thickness. As the hot melt polyurethane film, a hot melt polyurethane film (eg, a molecular weight of 20,000 to 30,000) that is commonly used is used.

Additionally, in order to increase the adhesive strength of the polyurethane layer 70 with the ink layer 50, a corona discharge is passed to ionize the surface of the polyurethane layer 70 to form an ionic bond between the ink and the ionized surface. It can increase the bonding force. In addition, the surface of the polyurethane layer 70 passes through the plasma to form partial radicals on the surface, and the surface has a partial hydrophilic function so that the surface is not covalently bound, but has a bonding force of Vandelwald's intermittent force and the ink molecules. Reaction and enhance its adhesive strength.

Next, the RP paper 80 / polyurethane layer 70 / polyurethane skin layer 60 / ink layer 50 / polyurethane adhesive layer 40 is laminated with the fabric 10 / polyurethane layer 30. By thermal pressing, both are combined and the RP paper 80 is removed to complete the printed laminate sheet shown in FIG.

7 is a table of the effect test results of the printed laminated sheet prepared according to the present disclosure. The test was conducted by the Korea Institute of Footwear and Leather Research (KIFLT), 786-50 Danggam-dong, Busan, Busan. The film peel strength (adhesive strength) was 6.1 N / mm. When converted into kg / cm, it can be seen that the value of 6.1x10 / 9.8 = 6.2kg / cm far exceeds the commercially available value of 4.5kg / cm.

Various embodiments of the present disclosure will be described below.

(1) fabric; And a composite layer coated with an ink layer on the polyurethane layer, the composite layer being formed on a fabric and having an ink in which the ink of the ink layer dissolves the polyurethane. Synthetic leather sheets have various applications such as shoes, vehicle seats, furniture, building materials, and clothing.

(2) A printing laminated sheet, wherein the polyurethane layer is located on the fabric side relative to the ink layer.

(3) A printing laminated sheet, wherein the polyurethane layer is located on the opposite side of the fabric relative to the ink layer, and the fabric is made of polyurethane on the side facing the ink layer.

(4) a printing laminated sheet comprising a; polyurethane adhesive layer between the fabric and the ink layer.

(5) a printing laminated sheet comprising a; polyurethane adhesive layer between the ink layer and the polyurethane layer.

(6) A printing laminated sheet, wherein the composite layer is provided with an ink layer, and has a polyurethane skin layer having physical properties that are relatively better dissolved in a solvent than a polyurethane layer.

(7) A printing laminated sheet, comprising a polyurethane skin layer which is applied with an ink layer, located between the polyurethane layer and the ink layer, and having a physical property in the solvent that is relatively better dissolved than the polyurethane layer.

(8) A printing laminated sheet, comprising: a polyurethane skin layer, to which an ink layer is applied, located between the ink layer and the polyurethane layer, and having a physical property in the solvent that is relatively better dissolved than the polyurethane layer.

(9) A printing laminated sheet, comprising a polyurethane skin layer coated with an ink layer and positioned between the ink layer and the polyurethane adhesive layer and having a physical property in the solvent that is relatively better dissolved than the polyurethane layer.

(10) A printing laminated sheet, wherein the ink is a pigment ink.

(11) A printing laminated sheet, wherein the ink has a particle size capable of digital printing.

(12) A printing laminated sheet, wherein the particle size is 2 μm or less.

(13) A printing laminated sheet, wherein the particle size is 1 um or less.

(14) A printing laminated sheet, wherein the solvent contains at least one of MEK, PMP, ANON, and DMF.

(15) A printing laminated sheet, wherein the ink encloses a pigment, and comprises at least one of propylene glycol, di-pyrrolididione, polyurethane alone, or a copolymer resin.

(16) A printing laminated sheet, wherein the ink has a particle size capable of digital printing.

According to one printing laminated sheet according to the present disclosure, it is possible to provide an adhesive strength between the reinforced printing layer and the polyurethane layer.

According to one printing laminated sheet according to the present disclosure, it is possible to provide a printing laminated sheet having an adhesive strength of 4.5kg / cm or more.

Ink layer: 50 Polyurethane layer: 30, 70

Claims (20)

fabric; And,
A composite layer coated with an ink layer on the polyurethane layer, which is formed on a fabric, and the ink of the ink layer has a composite layer having a solvent for dissolving the polyurethane. The method according to claim 1,
A printing laminated sheet, wherein the polyurethane layer is located on the fabric side relative to the ink layer. The method according to claim 1,
The polyurethane layer is located on the opposite side of the fabric relative to the ink layer,
A printing laminated sheet, wherein the fabric is made of polyurethane on the side facing the ink layer. The method according to claim 3,
Printed laminated sheet comprising a; polyurethane adhesive layer between the fabric and the ink layer. The method according to claim 3,
And a polyurethane adhesive layer between the ink layer and the polyurethane layer. The method according to claim 1,
The composite layer is a printing laminated sheet, characterized in that the ink layer is applied, and a polyurethane skin layer having a physical property that is relatively better dissolved in the solvent than the polyurethane layer. The method according to claim 2,
A printing laminated sheet, wherein the ink layer is applied, and is disposed between the polyurethane layer and the ink layer, and has a polyurethane skin layer having physical properties that are better dissolved in the solvent than the polyurethane layer. The method of claim 4,
A printing laminated sheet, wherein the ink layer is applied, and is disposed between the ink layer and the polyurethane layer, and has a polyurethane skin layer having a physical property in the solvent that is relatively better dissolved than the polyurethane layer. The method according to claim 5,
A printing laminated sheet, wherein the ink layer is applied, and is disposed between the ink layer and the polyurethane adhesive layer, and has a polyurethane skin layer having a physical property in the solvent that is relatively better dissolved than the polyurethane layer. The method according to claim 1,
The ink is a printing laminated sheet, characterized in that the pigment ink. The method according to claim 1,
The printing laminated sheet, characterized in that the ink has a particle size capable of digital printing. The method of claim 11,
Printing laminated sheet, characterized in that the particle size is 2um or less. The method of claim 12,
Printing laminated sheet, characterized in that the particle size is 1um or less. The method according to claim 1,
The solvent contains at least one of MEK, PMP, ANON, and DMF. The method of claim 10,
The ink is a vehicle surrounding the pigment (vehicle), the printed laminated sheet, characterized in that it comprises at least one of propylene glycol, di-pyrrolididione (2-Pyrrolidione), polyurethane alone or a copolymer resin. The method of claim 10,
The printing laminated sheet, characterized in that the ink has a particle size capable of digital printing. 18. The method of claim 16,
A polyurethane layer is located on the fabric side relative to the ink layer,
A printing laminated sheet, wherein the ink layer is applied, and is disposed between the polyurethane layer and the ink layer, and has a polyurethane skin layer having physical properties that are better dissolved in the solvent than the polyurethane layer. 18. The method of claim 16,
And a polyurethane adhesive layer between the fabric and the ink layer.
A printing laminated sheet, wherein the ink layer is applied, and is disposed between the ink layer and the polyurethane layer, and has a polyurethane skin layer having a physical property in the solvent that is relatively better dissolved than the polyurethane layer. 18. The method of claim 16,
And a polyurethane adhesive layer between the fabric and the ink layer.
A printing laminated sheet, wherein the ink layer is applied, and is disposed between the ink layer and the polyurethane adhesive layer, and has a polyurethane skin layer having a physical property in the solvent that is relatively better dissolved than the polyurethane layer. The method according to any one of claims 17 to 19,
Printing laminated sheet, characterized in that the particle size is 1um or less.

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