JPH03241092A - Slip-preventing varnish, slip-preventing processing with the same and production of corrugated board subjected to the same processing - Google Patents

Abstract

PURPOSE:To provide the subject varnish exhibiting a high slip-preventing effect and simultaneously an excellent blocking resistant property and useful for preparing corrugated boards by adding a specific ratio of a finely particulate organic filler to a varnish mainly comprising an aqueous tackifying agent and an alkali- soluble type water-soluble resin. CONSTITUTION:(C) 1-20wt.% of a finely particulate organic filler is added to a slip-preventing varnish mainly composed from (A) 100 pts.wt. of an aqueous tackifying agent and (B) 10-60 pts.wt. of an alkali-soluble type water-soluble resin to provide the objective varnish. The component A is preferably an aqueous emulsion such as the emulsion of ethylene/vinyl acetate copolymer having a glass transition temperature of <=5 deg.C and the component C has preferably particle diameters of 1-20mu and a softening point of >=180 deg.C.

Description

[Detailed Description of the Invention] <Industrial Application Field> The present invention relates to a non-slip varnish for preventing folding of paper containers such as cardboard boxes and cartons, and various paper bags, and also relates to the non-slip varnish. The present invention relates to a non-slip processing method using.

<Prior art and its problems> Agricultural products, marine products and other various foods, various industrial products, etc. are packaged and transported in paper containers such as cardboard, cartons, or various paper bags.

As logistics becomes more efficient, such as automation of various packaging lines and palletization of transportation lines, the collapse of cargo due to slipping of cardboard boxes, etc., has become a major problem. It is possible to prevent palletized cardboard cases from collapsing by banding or shrinking, but this increases costs, and a low-cost and highly safe anti-slip method is desired.

Conventionally, anti-slip varnishes such as those described below have been used to prevent paper cartons and paper bags from slipping. It had been constructed.

These anti-slip varnishes are adhesive type (retains adhesiveness even when dry after being applied to the surface of paper cartons, etc., and uses this adhesive strength to exert an anti-slip effect)
and non-adhesive type (coated on the surface of paper cartons, etc., and if necessary, subjected to appropriate treatment such as heating and foaming to form subtle irregularities on the surface, and these irregularities physically interlock with each other). 1!J which improves the coefficient of friction and prevents slipping) was used for boat fishing.

As the above-mentioned adhesive type anti-slip varnishes, emulsions of adhesive acrylic copolymers and ethylene/vinyl acetate copolymers are often used, and are applied by printing or coating using appropriate printing or coating means. Solid resins such as ethylene/vinyl acetate copolymer were also used and coated by heating and melting with special hot melt coating equipment.

Anti-slip paints made of rubber latex and water-based adhesives have also been proposed.

On the other hand, the latter non-adhesive type is made by mixing fine inorganic particles such as silicic anhydride or a foaming agent that foams when heated in a resin binder such as water-based ink or water-based paint. After printing and coating by printing or coating means, an uneven surface was formed by the fixed fine particles or the foaming agent particles whose volume expanded due to heating.

<Problems to be Solved by the Invention> However, with the above-mentioned adhesive type, since the coated surface is sticky after drying, blocking occurs, damaging the surface of paper containers, etc., or causing dirt and dust to accumulate during transportation. The commercial value of the paper carton was significantly lowered, such as by adhering to it and making it dirty.

In addition, in the case of copolymer emulsions with various adhesive properties, there is a problem that the anti-slip effect cannot be obtained if attempts are made to prevent the occurrence of blocking, and in the case of solid resins, they can be applied by heating and melting. Since this method requires special equipment for printing, printing machines for folding cartons and paper bags cannot be used as is, resulting in a problem of reduced work efficiency.

Anti-slip paints made of rubber latex and water-based adhesives can be expected to have some anti-blocking effect, but
The abrasion resistance was insufficient and had problems.

In addition, in the case of the latter non-adhesive type, although the initial slip prevention effect can be expected to some extent, the anti-slip effect deteriorates extremely when reloading operations are repeated, and the sustainability of the anti-slip effect is lacking. Furthermore, while the abrasion resistance is poor, as a result of using a large amount of inorganic particles, the varnish inevitably tends to whiten, lacks cosmetic properties, and has some practical limitations. Furthermore, the use of inorganic particles has the problem of accelerating wear of the doctor blade and anilox roller of the coating machine.

Furthermore, conventional anti-slip varnishes do not have sufficient heat resistance; for example, in corrugated board manufacturing, the liner for corrugated board production is printed and coated with anti-slip varnish in advance, and then the core and back liner are coated with a corrugator. When applied to a bonding system, it has the following problems.

In other words, in the case of the adhesive type, the coated surface must exhibit adhesiveness after drying, so there are limits to the softening point and molecular weight of the resin used, and it is not possible to increase the heat resistance temperature. Ta. Therefore, when a front liner coated with these varnishes is laminated in a corrugator, the resin softens, causing hot plate stains and further damaging the corrugated board. On the other hand, when the softening point of the resin is raised to a sufficient heat-resistant temperature, the anti-slip effect decreases, and conventional adhesive type anti-slip varnishes cannot be applied to this method.

On the other hand, the non-adhesive type smoothes out unevenness due to friction with the hot plate inside the corrugator, resulting in a significant drop in anti-slip effect, and is similarly not suitable for this type of corrugated board manufacturing system. It was something that didn't exist.

The present invention aims to solve the above-mentioned problems of conventional anti-slip varnishes, and has superior anti-slip effects, as well as transparency (no whitening phenomenon), anti-blocking properties, and anti-friction properties. The purpose is to provide an anti-slip varnish with excellent properties.

The present invention also aims to provide an anti-slip varnish that causes less wear on the dot blades and anilox rollers of coating machines.

The present invention also provides a heat-resistant anti-slip varnish for corrugators.

Further, the present invention provides a method of making the above-mentioned anti-slip varnish anti-slip using the same, and a method of producing corrugated board treated with anti-slip.

<Means for Solving the Problem> The present invention corresponds to an improved adhesive type anti-slip varnish, and the present invention combines an aqueous adhesive with a glass transition temperature within a specific range and an alkali-soluble water-soluble varnish. It is an object of the present invention to provide an anti-slip varnish characterized in that a specific proportion of a fine particle organic filler is further added to a mixture of a resin and a specific proportion.

The water-based adhesive used in the anti-slip varnish of the present invention must have properties that provide adhesiveness even in a dry state after being applied to paper containers, etc., and must have sufficient compatibility with the alkali-soluble water-soluble resin described below. It must have the following characteristics. As the water-based adhesive that can be applied to such a purpose, an adhesive having a glass transition temperature (Tg) of 5°C or less, more preferably 0°C to -40°C can be used. If Tg exceeds 5°C, the anti-slip effect will not be sufficient and
When the temperature is lower than 0'C, problems such as blocking are likely to occur.

As the water-based adhesive which is one component of the anti-slip varnish according to the present invention, water-based emulsions such as ethylene/vinyl acetate copolymer emulsion, acrylic copolymer emulsion, urethane emulsion, and rubber latex can be used. .

Ethylene 7/vinyl acetate copolymer emulsion (hereinafter simply referred to as EVA emulsion) requires properties that provide tackiness even in a dry state when applied to paper containers, etc., and an alkali-soluble water-soluble type as described below. It must have sufficient compatibility with the polymeric resin.

EVA emulsions that can be used for this purpose have a viscosity of 300 to 5,000 centivoise and can be used to form a film at room temperature.

If the viscosity of the emulsion is outside the above range, the printability will be insufficient, and if the emulsion does not form a film at room temperature, a special heating device will be required, which is not preferable in terms of the work process.

Specific examples of EVA emulsions having these properties include Polysol EVA P-20, P3 (manufactured by Showa Kobunshi Co., Ltd.), Denka EVA Tex #20, #60 (manufactured by Denki Kagaku Kogyo Co., Ltd.), Sumikaflex 400.401.
450.610.460 (manufactured by Sumitomo Chemical Industries, Ltd.) and the like. These emulsions have a solid content of 35 to 60
It is within the range of .

In addition, the acrylic copolymer emulsion has the above-mentioned performance as an adhesive, and includes (meth)acrylic acid alkyl esters, such as methyl, ethyl, propyl, isopropyl, n-butyl, S-butyl, and t-butyl. , esters having linear or side chain alkyl groups such as hexyl, 2-ethylhexyl, decyl, lauryl, etc., styrenes, <meth>acrylic acid, unsaturated acids such as maleic acid, and other polymerizable acids, if necessary. Examples include those obtained by emulsion polymerization with vinyl compounds and the like.

In addition, as the urethane emulsion, a self-emulsifying type synthesized from polyol and organic diisocyanate, etc. or a sticky emulsion dispersed in the presence of an activator can be used, and the glass transition temperature is 5°C to -4°C.
It is at 0°C.

Specific examples of urethane emulsions having these properties include SunCure 776.822A, 849.86
7.889 (manufactured by Gunze Sangyo Co., Ltd.) is an example. The solids content of these emulsions ranges from 35 to 60.

Further, as the rubber latex, natural rubber or a synthetic rubber latex selected from styrene/'butadiene rubber, polychloroprene rubber, nitrile rubber or polyimprene rubber can be used, and these can be used alone or in the form of a mixture.

These rubber latexes have a solid content of 40 to 60% by weight and are alkaline (usually have a pH of 7 to 12).

Among the water-based adhesives listed above, it is difficult to obtain high abrasion resistance with urethane emulsions and rubber latexes, and in applications where this suitability is important, EVA emulsions or acrylic copolymer emulsions are recommended. It is desirable to use it.

In addition, the alkali-soluble water-soluble resin to be used in combination with the above-mentioned water-based adhesive has a molecular weight of 5000 to 60000, an acid value,
A range of 80 to 300 is preferred. If the molecular weight is less than 5,000, the anti-blocking effect will be poor, if it is more than 60,000, there will be problems with solubility and printing suitability, and if the acid value is less than 80, it will be difficult to make it into 7 volumes of water. On the other hand, if it is more than 300, the water resistance or sliding effect will be poor.

In addition, it is necessary that the alkali-soluble aqueous resin has a Tg of 60°C or higher, more preferably 80°C or higher,
If Tg is low, it will be difficult to obtain sufficient anti-blocking effect and heat resistance even if a large amount of organic filler is used.

Specific examples of these alkali-soluble water-soluble resins include styrene/maleic acid copolymer, styrene/acrylic copolymer, rosin-modified maleic resin, acrylic resin, maleic acid resin, etc. Or two or more types can be used in combination.

In the anti-slip varnish according to the present invention, the mixing ratio of the water-based adhesive and the alkali-soluble water-soluble resin is important; the solid content of the latter is 10 to 60 parts by weight per 100 parts by weight of the former. It is necessary that the amount be within the range of parts by weight. When the former ratio is high, blocking resistance and heat resistance become a problem, and in the opposite case, the anti-slip effect becomes a problem.

Further, the organic particulate filler can be added in an amount of 1 to 20 weight 9, preferably 3 to 15 weight 3L9≦ in the anti-slip varnish. If it is less than 125, the blocking resistance will not be sufficient, and if it is more than 20%, problems will occur such as a decrease in coating/printing suitability, abrasion resistance, and fluidity of the varnish. Furthermore, the particle size of these organic fillers can range from 1 to 20 microns. If the particle size is smaller than the range, the anti-blocking effect cannot be obtained, and if it is larger, problems arise in printing/coating suitability.

In addition, if heat resistance (corrugator suitability) is required,
The softening point of the organic filler is preferably 180°C or higher, more preferably 200°C or higher, and the particle size is
It is desirable to select a relatively large one (10μ or more).

Specific examples of organic fillers include fine particles obtained from resins such as acrylic, styrene, styrene/acrylic, ethylene, acrylic, nylon, polyester, polyethylene, polypropylene, vinyl chloride, acrylonitrile, phenol, epoxy, polyamide, silicone, and polyurethane. Powders can be used alone or in mixtures.

The anti-slip varnish according to the present invention has the above three components as its main components, but may also contain antifoaming agents, viscosity adjustment, dryness adjustment, or various additives to improve printing suitability as necessary. It is something that can be added.

Effect> The anti-slip varnish according to the present invention is a mixture of a water-based adhesive having a glass transition temperature within a specific range and an alkali-soluble water-soluble resin in a specific proportion, and a fine particle organic filler in a specific proportion. It is characterized by the addition of
Its effect can be considered as follows.

In other words, in the case of conventional adhesive type anti-slip varnishes, an adhesive layer was formed on the surface of the applied varnish, thereby obtaining the anti-slip effect. It was impossible to increase the ratio. On the other hand, the varnish according to the present invention has a high adhesive ratio to the point where blocking would normally occur, but by adding a predetermined amount of organic filler to it, it can be applied evenly on the coated varnish surface. It is thought that the organic filler layer acts as a kind of barrier to prevent direct contact and prevent the blocking phenomenon from occurring. In addition, when cardboard etc. are stacked and a load is applied, the organic filler is pushed into the layers and the adhesive layer comes into direct contact, providing a high anti-slip effect, but when the load is removed, the organic filler is pushed out. , it is thought that a peeling phenomenon occurs in micron units and prevents the occurrence of blocking.

In addition, the reason why it is possible to obtain superior anti-slip and anti-blocking performance compared to the addition of inorganic fillers is that the specific gravity is lower than that of inorganic fillers, so when a varnish is applied, particles do not form on the surface of the coating film. This is thought to be due to the lifting and efficient distribution on the coating surface.

In addition, regarding heat resistance and corrugator resistance, an organic filler layer with a high softening point uniformly formed on the coated varnish surface prevents direct contact between the hot plate and the adhesive layer. As a result, it is thought that the occurrence of mature board stains or deterioration of the anti-slip effect will not occur.

Now, regarding the application of the anti-slip varnish according to the present invention, it is possible to apply it by means such as roller coating or spraying after making the box or bag, but from the viewpoint of improving work efficiency, it is not possible to apply the anti-slip varnish to paper cartons or paper bags. It is preferable to carry out this process during the printing process. Specifically, the remaining final printing unit of the printing machine can be used to print paper cartons and the like and simultaneously coat with anti-slip varnish.

Next, a method for manufacturing corrugated board using the anti-slip varnish with excellent heat resistance according to the present invention will be explained. The anti-slip varnish according to the present invention exhibits an excellent anti-slip effect when applied to corrugated cardboard and paper cartons, and also has high heat resistance against hot plates of corrugators. .

Therefore, the anti-slip varnish with excellent heat resistance according to the present invention is extremely effective when applied to the preprint method that has recently been used in corrugated board manufacturing. That is, in the present invention, after applying the anti-slip varnish with excellent heat resistance according to the present invention to the surface of the front liner printed by a rotary press, the front liner, the center core, and the back liner are laminated using a corrugator machine. The present invention provides a method for manufacturing corrugated cardboard with anti-slip processing.

First, a process of printing by rotary printing on the surface of the front liner used in corrugated board manufacturing will be explained.

In conventional printing of corrugated board, a front liner, a center core, and a back liner are pasted together, and the corrugated board is cut to an appropriate size, and printing is performed using a sheet-fed flexo printing machine or the like. In contrast, in the method of the present invention,
Printing is carried out continuously on a web-like front liner in a rotary manner.

This printing process does not have the same limitations as conventional printing methods such as corrugated board printing, and rotary printing methods include flexo printing, gravure printing, rotary planographic printing, and even rotary screen printing. These means can be conveniently used.

In recent years, as a method of manufacturing high-grade corrugated board, web-shaped front liners are printed using water-based or solvent-based flexographic or gravure inks, and the resulting material is rolled up and used as a mill roll stand for the front liners of corrugator machines. A method of manufacturing corrugated board by so-called preprinting, in which the corrugated board is installed and laminated with a core and a back liner, has been implemented.

Therefore, the front liner is printed using the various printing inks and the printing machine used for this, and after the required printing has been applied to the front liner, it is wound up once. It is also possible to print the front liner and apply the anti-slip varnish continuously in-line.
This can be achieved by using the last printing unit of the printing press for applying the anti-slip varnish, or by installing various coating devices for application after the printing press.

In addition, when applying anti-slip varnish in-line with printing, it can be applied to the entire surface or only partially to the necessary areas using methods such as roll coating, curtain coating, spray coating, gravure printing, and flexographic printing. I can do it. Also,
It is also possible to attach the printed surface liner as it is to the mill roll stand of the corrugator machine and apply an anti-slip varnish using a liner roll coater installed in the corrugator machine.

Here, if a front liner coated with a conventional non-slip varnish is used and laminated with the core and back liner in a corrugator machine, the temperature of the hot plate is 160°C. At temperatures of up to 190°C, the anti-slip effect deteriorates, and the softened resin stains the hot plate, which significantly reduces the commercial value of the corrugated board. If used, the anti-slip effect will not deteriorate and the problem of hot plate staining will not occur.

Therefore, when carrying out the method of the present invention, when using a front liner that has been previously printed and coated with anti-slip varnish, it is necessary to use a printed front liner that is wound up on a mill roll stand for the front liner. If the varnish is not applied to the printed front liner, it will be applied to the printed front liner by the coating device installed either before or after the front liner preheater, and the varnish will be applied to the center core and back side before the double facer. By laminating the liner, a corrugated board with the desired anti-slip finish is produced.

In addition, in carrying out the method of the present invention, there are few cases in which unprinted corrugated board is produced, and in many cases a printed front liner is pasted, so a cutting device that cuts the paperboard based on the printed pattern is installed. There is a need. By performing necessary cutting and the like using the above-mentioned cutting device, it is possible to obtain corrugated cardboard with the desired anti-slip finish.

EXAMPLES Hereinafter, the present invention will be explained in more detail with reference to Examples, but the present invention is not limited thereto.

<Example> Here, first, the components of the anti-slip varnish manufactured in the example (
Water-based adhesive, water-soluble resin, organic filler) will be explained respectively.

Water-based adhesive Adhesive A: EVA emulsion, Sumikaflex 4
00, manufactured by Sumitomo Chemical Co., Ltd. (viscosity 1300 cps, solid content 50%, Tg -15°C) Adhesive B Niacrylic emulsion, Movinyl 937 (manufactured by Hoechst Gosei Co., Ltd.) (solid content 60%, Tg, -40°C) Adhesive C: Manufactured by Japan Synthetic Rubber Co., Ltd., SBR latex No. 0598 (solid content 50%, Tg, -20°C) 444 Sengyoto Water-soluble resin A: Methyl memethallate, 65.1% by weight,
An ammonia aqueous solution of an alkali-soluble resin (water-soluble resin A) consisting of methacrylic acid, 231% by weight, and 881% styrene. (Solid content 25% by weight, Tg, 121°C) Water-soluble resin B: Methyl memethallate, 52.4% by weight,
Acrylic acid, 21.8% by weight, styrene 11.8% by weight
, butyl acrylate, an ammonia aqueous solution of an alkali-soluble resin (water-soluble resin B) consisting of 14.0% by weight (solid content 25 weight ? 6, Tg, 69.8°C) Organic fine particles Base: The organic fine particles are as follows. resin powder is used.

Organic fine particles A: Boristyrene, average particle size, 6μ (softening point 200°C) Organic fine particles B: Nylon, average particle size, 12μ, (softening point 160°C) Organic fine particles C: ethylene-acrylic, average particle size 10μ (
Softening point: 100°C) Organic fine particles D: Boristyrene, average particle size, 12μ (softening point: 200°C) Organic fine particles D: Polystyrene, average particle size, 3μ (softening point: 200°C) Examples 1 to 9 and Comparative Examples 1 to 5 Adhesives A to C1, water-soluble resins A and B, and particulate fillers A to C as explained in Table 1 are mixed together, a small amount of water and an antifoaming agent are added, and an anti-slip varnish is applied. Adjust each.

Evaluation Test 1 Using each of the anti-slip varnishes obtained in Examples 1 to 9 and Comparative Examples 1 to 3, the anti-slip varnishes obtained in Examples 1 to 9 and Comparative Examples 1 to 1 were applied in a solid manner to a cardboard liner using a bar coater in an amount of about 4? / m2, conditioned for one day at 20℃ and 60% humidity, and TA
The sliding angle was measured according to the slope test specified by PPI.

In addition, regarding blocking, the same a! The humidity is controlled, the varnished surfaces are placed one on top of the other, and a load of 5 kg/25 cal is applied for evaluation.

Regarding transparency, the dry coating film of the anti-slip varnish is visually evaluated.

Regarding the abrasion resistance, each varnish was applied in a solid manner using a bar coater onto the liner for corrugated board printed with water-based flexo ink at a solid coating amount of approximately 47/rn2.
500g using a 7-shape friction tester.
Under the conditions of 500 load cycles, evaluation was made as ○ for no stains, Δ for some stains, and X for many stains.

Furthermore, the storage stability of the anti-slip varnish (degree of separation or sedimentation of the filler) and the degree of wear of the doctor blade when each anti-slip varnish is placed in a gravure coater and operated for a long time are evaluated.

In addition, in the case of a liner not coated with varnish at all, it was evaluated in the same manner as a blank.

The above evaluation results are added to Table-1.

Examples 10 to 12 The previously described adhesive A, water-soluble resins A and B, and particulate fillers A, D, and E were mixed to have the composition shown in Table 2,
Adjust each anti-slip varnish.

Evaluation Test 2 Using the anti-slip varnishes of Examples 1 to 5.9 and 10 to 12 and Comparative Examples 1 to 5, the same slip angle as in Evaluation Test 1 was obtained.
While evaluating blocking resistance, the following heat resistance evaluation test is conducted. Regarding heat resistance, apply the varnished surface to aluminum foil and heat it at 180°C 55kg y'c
Pressure is applied for 3 seconds under a load of rA, and the degree of transfer of varnish to aluminum is evaluated.

Furthermore, the liner for corrugated board printed by rotary printing using water-based flexographic ink is coated with the above-mentioned heat-resistant non-slip varnish, and this is used as the front liner and laminated with the core and back liner using a corrugator. Then, corrugated cardboard is manufactured, and the presence or absence of hot plate stains and the sliding angle after passing through a corrugator are measured.

The results of each of the above evaluations are added to Table 2.

In the anti-slip varnishes of Examples 2 and 3, it was difficult to obtain sufficient heat resistance because the softening point of the organic filler used was low, and even when water-based resin B with a low glass transition temperature was used as the water-based resin. , it is difficult to obtain sufficient heat resistance. Therefore, in order to obtain sufficient heat resistance (corrugator suitability), it is necessary to use an organic filler with a high softening point and an aqueous resin with a high glass transition temperature.

Effectiveness> As is clear from the above description, the anti-slip varnish according to the present invention exhibits an extremely high anti-slip effect compared to conventional adhesive type anti-slip varnishes, and also exhibits excellent blocking resistance. Compared to the use of inorganic fillers, it has superior transparency and suitability for printing and coating.

Furthermore, in the case of a heat-resistant varnish, it can be effectively applied to the so-called preprint corrugated board manufacturing method that has been implemented recently.

Claims (9)

[Claims] (1) 100 parts by weight (solid content) of water-based adhesive, 10 to 6 parts of alkali-soluble water-soluble resin with a glass transition temperature of 60°C or higher
1 to 20% by weight of particulate organic filler based on the total amount of anti-slip varnish mainly composed of 0 parts by weight (solid content)
An anti-slip varnish characterized by the addition of (solid content). (2) The anti-slip varnish according to claim 1, wherein the aqueous adhesive is an aqueous emulsion having a glass transition temperature of 5° C. or less. (3) The anti-slip varnish according to claim 2, wherein the aqueous emulsion is selected from an ethylene/vinyl acetate copolymer emulsion and an acrylic copolymer emulsion. (4) The anti-slip varnish according to claim 1, which has excellent heat resistance, wherein the alkali-soluble water-soluble resin has a glass transition temperature of 100° C. or higher. (5) The anti-slip varnish according to claim 1, wherein the particle size of the particulate organic filler is 1 to 20 microns. (6) The anti-slip varnish according to claim 5, which has excellent heat resistance, wherein the particulate organic filler has a softening point of 180° C. or higher. (7) A non-slip processing method comprising applying the non-slip varnish according to any one of claims 1 to 6 on the surface of a paper carton or paper bag to form a non-slip coating. (8) The anti-slip processing method according to claim 7, wherein the smooth varnish is applied during the printing process of the paper carton or paper bag. (9) After applying the anti-slip varnish according to claim 4 or 6 to the printed front liner for manufacturing corrugated board, the front liner is laminated with the core and back liner using a corrugator machine to manufacture corrugated board. A method for manufacturing corrugated board with anti-slip processing, characterized by: