阅读说明：本技术 pH感应型变色油墨组合物以及使用其的pH感应型指示标签和包装材料 (pH sensitive color change ink composition, and pH sensitive indicator label and packaging material using the same ) 是由 金度完 赵京植 金芝暎 洪锡準 于 2020-05-22 设计创作，主要内容包括：本申请涉及一种pH感应型变色油墨组合物和使用其的pH感应型指示标签和包装材料,其中,所述pH感应型变色油墨组合物包括pH感应型指示剂,其由根据pH区间而改变颜色的多个pH变色染料混合制成；溶解油墨,其与所述pH感应型指示剂一起搅拌并溶解所述pH感应型指示剂；吸附化合物,其与所述溶解油墨一起搅拌并能够吸附气体,并且使用pH感应型变色油墨组合物的pH感应型指示标签和包装材料使用pH感应型变色油墨组合物。(The present invention relates to a pH sensitive color change ink composition and a pH sensitive indicator label and a packaging material using the same, wherein the pH sensitive color change ink composition includes a pH sensitive indicator made by mixing a plurality of pH color change dyes that change color according to a pH range; a dissolving ink that is stirred together with the pH responsive indicator and dissolves the pH responsive indicator; an adsorption compound which is stirred with the dissolved ink and is capable of adsorbing gas, and a pH sensitive discoloration ink composition is used using a pH sensitive discoloration ink composition for a pH sensitive discoloration ink label and a packaging material.)

1. A pH sensitive color change ink composition that changes color as a result of a reaction, comprising:

a pH sensitive indicator made by mixing a plurality of pH color-changing dyes that change color according to a pH interval;

a dissolving ink that is stirred together with the pH responsive indicator and dissolves the pH responsive indicator;

an adsorption compound that is stirred together with the dissolved ink and is capable of adsorbing gas,

wherein the ink composition is changed into a plurality of colors according to a change in pH by the pH sensitive indicator mixed with the plurality of pH color-changing dyes.

2. The pH sensitive color change ink composition according to claim 1,

the color-changing ink composition changes color by changing pH due to gas adsorption.

3. The pH sensitive color change ink composition according to claim 1,

the adsorbent compound comprises polyethyleneimine.

4. The pH sensitive color change ink composition according to claim 1,

the adsorbing compound changes the pH of the color changing ink composition by adsorbing carbon dioxide.

5. The pH sensitive color change ink composition according to claim 1,

the weight ratio of the adsorbed compound to the weight of the dissolved ink is 0.5% to 10%.

6. The pH sensitive color change ink composition according to claim 1,

the dissolving ink comprises

25 to 45 weight percent resin, 1 to 3 weight percent additive, and 52 to 74 weight percent solvent.

7. The pH sensitive color change ink composition according to claim 1,

the weight ratio of the pH responsive indicator to the weight of the dissolved ink is 0.4% to 5%.

8. The pH sensitive color change ink composition according to claim 1,

the pH sensitive indicator includes two or more of thymol blue, methyl red, bromothymol blue, phenolphthalein, phenol red, and bromocresol green.

9. The pH sensitive color change ink composition according to claim 1,

the dissolving ink includes an additive including an ethanol type urethane resin and an ethanol solvent.

10. A pH responsive indicator label using an ink composition that changes color by reaction, the pH responsive indicator label comprising:

a pH sensitive color changing ink composition layer comprising the pH sensitive color changing ink composition according to any one of claims 1 to 9;

a first film on which the pH sensitive color change ink composition layer is formed;

a second film laminated to the first film to cover the pH sensitive color changing ink composition formed on the first film.

11. The pH responsive indicator label of claim 10,

a non-color changing ink composition layer is formed on the first film on which the pH sensitive color changing ink composition is formed,

the non-color changing ink composition layer includes at least one of a white ink composition layer and a colored ink composition layer.

12. The pH responsive indicator label of claim 10,

the indicating layer including the pH sensitive color changing ink composition layer formed on the first film includes the pH sensitive color changing ink composition and the non-color changing ink composition,

the indicating layer of the first film is formed by alternating at least one of the pH sensitive color changing ink compositions and at least one of the non-color changing ink compositions on one surface of the first film.

13. A pH sensitive indicating packaging material using an ink composition that changes color by reaction, the pH sensitive indicating packaging material comprising:

a container having a product inserted therein;

a through hole passing through the container in a region not in contact with the product;

a label attached to the through-hole,

wherein the tag comprises:

a pH sensitive color changing ink composition layer comprising the pH sensitive color changing ink composition according to any one of claims 1 to 9;

a first film on which the pH sensitive color change ink composition layer is formed;

a second film laminated to the first film to cover the pH sensitive color changing ink composition formed on the first film.

14. A pH sensitive indicating packaging material using an ink composition that changes color by reaction, the pH sensitive indicating packaging material comprising:

a container having a product inserted therein;

a pH sensitive color changing ink composition layer comprising the pH sensitive color changing ink composition according to any one of claims 1 to 9 and formed in a region not in contact with the product in the inside of the container.

15. A pH responsive indicator packaging material according to claim 14,

a part of the inside of the container including the pH color-changing ink composition layer is formed with a through hole.

Technical Field

The present invention relates to a pH sensitive color change ink composition and a pH sensitive indicator label and a packaging material using the same, and more particularly, to a pH sensitive color change ink composition and a pH sensitive indicator label and a packaging material using the same, in which a pH sensitive indicator is made by mixing a plurality of pH color change dyes so that the pH sensitive color change ink composition can be changed into a plurality of colors according to a change in pH.

Background

Recently, food is packaged in a packaging material for sale, and consumers are more expected to confirm the freshness and state of food to purchase the food in addition to the requirements for quantity, quality, convenience and stability when purchasing the food.

Foods packaged with a packaging material may change their freshness and state with the passage of time, but there is a problem in that it is difficult to confirm the freshness and state of foods before the packaging material is opened and the foods are confirmed. To solve this problem, an indicator for confirming the freshness and status of food without opening the packing material is being developed.

However, the conventional indicator has the following problems. The freshness and state of food may be variously changed with the passage of time, but it is difficult for the existing indicator to inform the consumer by reflecting all of various changed states of food.

For example, for a cookie, it may be in the state of a fresh cookie, a proper ripening period, and a late ripening period according to the passage of time, but the existing indicator has difficulty in notifying the consumer by reflecting all the various changed states of the cookie.

Disclosure of Invention

Technical problem

The present application has been made to solve the above-mentioned problems, and more particularly, to a pH sensitive color change ink composition and a pH sensitive indicator label and a packaging material using the same, in which a pH sensitive indicator is made by mixing a plurality of pH color change dyes so that the pH sensitive color change ink composition can be changed into a plurality of colors according to a change in pH.

Technical scheme

The pH sensitive color change ink composition of the present application for solving the above problems may include: a pH sensitive indicator made by mixing a plurality of pH color-changing dyes that change color according to a pH interval; a dissolving ink that is stirred together with the pH responsive indicator and dissolves the pH responsive indicator; an adsorption compound that is stirred together with the dissolved ink and is capable of adsorbing gas, wherein the ink composition is changeable into a plurality of colors according to a change in pH by the pH sensitive indicator mixed with the plurality of pH-changing dyes.

The color change ink composition of the pH sensitive color change ink composition of the present application for solving the above problems may change color by changing pH due to adsorption of gas.

The adsorption compound of the pH sensitive color change ink composition of the present application for solving the above problems may include polyethyleneimine.

The adsorption compound of the pH sensitive color change ink composition of the present application for solving the above problems may change the pH of the color change ink composition by adsorbing carbon dioxide.

The adsorption compound of the pH sensitive color change ink composition of the present application for solving the above problems may be present in a weight ratio of 0.5% to 10% with respect to the weight of the dissolved ink.

The dissolved ink of the pH sensitive color change ink set of the present application for solving the above problems may include 25 to 45% by weight of a resin, 1 to 3% by weight of an additive, and 52 to 74% by weight of a solvent.

The pH sensitive indicator of the pH sensitive color change ink composition of the present application for solving the above problems may be 0.4 to 5% by weight with respect to the weight of the dissolved ink.

The pH sensitive indicator of the pH sensitive color change ink composition of the present application for solving the above problems may include two or more of Thymol Blue (Thymol Blue), Methyl Red (Methyl Red), Bromothymol Blue (Bromothymol Blue), Phenolphthalein (Phenolphthalein), Phenol Red (Phenol Red), and Bromocresol green (Bromocresol green).

The dissolving ink of the pH sensitive color change ink composition of the present application for solving the above problems may include an additive including an ethanol type urethane resin and an ethanol solvent.

The pH sensitive indicator label of the present application for solving the above problems may include: a pH sensitive color changing ink composition layer comprising a pH sensitive color changing ink composition; a first film on which the pH sensitive color change ink composition layer is formed; a second film laminated onto the first film to cover the pH sensitive color changing ink composition formed on the first film.

The pH sensitive indicator label of the present application for solving the above problems may have a non-color changing ink composition layer formed on the first film on which the pH sensitive color changing ink composition is formed, and the non-color changing ink composition layer may include at least one of a white ink composition layer and a color ink composition layer.

The indicating layer of the pH sensitive color change ink composition of the present application for solving the above problems may include the pH sensitive color change ink composition and the non-color change ink composition, and the indicating layer of the pH sensitive color change ink composition including the first film may be formed by alternating at least one of the pH sensitive color change ink composition and at least one of the non-color change ink composition on one surface of the first film.

The pH sensitive indicator packaging material of the present application for solving the above problems may include: a container having a product inserted therein; a through hole passing through the container in a region not in contact with the product; a label attached to the through hole, wherein the label may include: a pH sensitive color changing ink composition layer comprising a pH sensitive color changing ink composition; a first film on which the pH sensitive color change ink composition layer is formed; a second film laminated to the first film to cover the pH sensitive color changing ink composition formed on the first film.

The pH sensitive indicator packaging material of the present application for solving the above problems may include: a container having a product inserted therein; a pH responsive color changing ink composition layer comprising a pH responsive color changing ink composition and formed in a region of the inside of the container not in contact with the product.

A part of the inside of the container of the pH sensitive indicator packaging material of the present application including the pH-changing ink composition layer may be formed with a through-hole for solving the above problems.

Advantageous effects

According to the present application, a pH sensitive indicator may be manufactured by mixing a plurality of pH-changing dyes such that the ink composition can be changed in color into various colors according to a change in pH, thereby enabling various states of a product to be informed to a consumer.

In addition, the present application can determine the state of the product in a non-contact manner with the product since the state of the product is discriminated by the gas generated from the product.

Drawings

Fig. 1(a) and 1(b) are diagrams illustrating a label using a pH sensitive color change ink composition according to an embodiment of the present application.

Fig. 2(a) to 2(c) are diagrams illustrating a non-color-changing ink composition layer according to an embodiment of the present application.

Fig. 3(a) to 3(c) are diagrams showing a configuration relationship of a color-changing ink composition layer and a non-color-changing ink composition layer according to an embodiment of the present application.

Fig. 4(a) and 4(b) are diagrams illustrating that a second film of a label using a pH sensitive color change ink composition according to an embodiment of the present application is laminated to a first film through an adhesive.

Fig. 5 is a view showing a packaging material to which a label using a pH sensitive color change ink composition according to an embodiment of the present application is attached.

Fig. 6 is a diagram illustrating a packaging material printed with a pH sensitive color change ink composition according to an embodiment of the present application.

Fig. 7 is an example of applying a label to a container having a through-hole formed therein and placing a cookie in the container for testing according to an embodiment of the present application.

Fig. 8 is a graph comparing visibility of an example in which a colored ink composition layer is formed with an example in which a colored ink composition layer is not formed according to an example of the present application.

Best mode

The pH sensitive color change ink composition according to an embodiment of the present application may include: a pH sensitive indicator made by mixing a plurality of pH color-changing dyes that change color according to a pH interval; a dissolving ink that is stirred together with the pH responsive indicator and dissolves the pH responsive indicator; an adsorption compound that is stirred with the dissolved ink and is capable of adsorbing gas.

The pH sensing type indicator label according to an embodiment of the present application may include: a pH sensitive color changing ink composition layer comprising a pH sensitive color changing ink composition; a first film on which the pH sensitive color change ink composition layer is formed; a second film laminated to the first film to cover the pH sensitive color changing ink composition formed on the first film.

A pH sensitive indicator packaging material according to embodiments of the present application may include: a container having a product inserted therein; a through hole passing through the container in a region not in contact with the product; a label attached to the through hole, wherein the label may include: a pH sensitive color changing ink composition layer comprising a pH sensitive color changing ink composition; a first film on which the pH sensitive color change ink composition layer is formed; a second film laminated to the first film to cover the pH sensitive color changing ink composition formed on the first film.

A pH sensitive indicator packaging material according to embodiments of the present application may include: a container having a product inserted therein; a pH responsive color changing ink composition layer comprising a pH responsive color changing ink composition and formed in a region of the inside of the container not in contact with the product.

Detailed Description

The description sets forth the scope of the application, illustrates the principles of the application and discloses embodiments so that others skilled in the art can practice the application. The disclosed embodiments may be implemented in various forms.

Expressions such as "comprise" or "may comprise" that may be used in various embodiments of the present application indicate the presence of the corresponding function, operation, or component of the disclosure (disclosure), and may include one or more additional functions, operations, or components without limitation. Furthermore, in the embodiments of the present application, terms such as "including" or "having" are intended to indicate that there are features, numbers, steps, operations, components, parts, or combinations thereof described in the specification, and it should be understood that they do not exclude the possibility of adding or having one or more other features or numbers, steps, operations, components, parts, or combinations thereof.

Embodiments of the present application will be described in detail below with reference to the accompanying drawings.

The pH sensitive color change ink composition according to an embodiment of the present application includes a pH sensitive indicator, a dissolved ink, and an adsorption compound.

The pH responsive indicator is made by mixing a plurality of pH color-changing dyes that change color according to a pH interval. In order to inform consumers of various states of products, it is necessary to change colors according to the various states of the products. However, since the pH-variable dye is changed into only two or three colors according to the pH interval, there is a problem in that it is difficult to reflect all of various states of the product.

The pH responsive indicator, which is used to solve this problem, is made by mixing a plurality of pH discoloration dyes, and by which a pH responsive discoloration ink composition can be discolored into various colors according to a change in pH.

The pH-sensitive indicator may use a pigment whose color varies depending on pH, and the kind thereof is not particularly limited, but may be mixed with a pigment selected from, for example, Alizarin Blue (Alizarin Blue), Methyl Violet (Methyl Violet), o-Cresol Red (o-Cresol Red), Crystal Violet (Crystal Violet), erythrosine (Erythrosin), Thymol Blue (Thymol Blue), m-Cresol Red (m-Cresol Red), Methyl Violet 6B (Methyl Violet 6B), p-Aminoazobenzene (Aminoazobenzene), Alizarin Yellow r (Alizarin Yellow r), β -Dinitrophenol (2, 6-Dinitrophenol)), Methyl Orange (Methyl Orange), Congo Red (Congo Red), p-Ethyl Orange (p-Ethyl Orange), naphthored (naphthored), Methyl Red (Methyl Red), Thymol (Blue), chlorocresol (Blue bromide), Thymol Blue (Blue bromide), and mixtures thereof, One or more, two or more, three or more, or four or more of Phenol Red (Phenol Red), Neutral Red (Neutral Red), Bromocresol green (bromocrasol green), and Phenolphthalein (Phenolphthalein). Alternatively, two or more, or three or more, or four or more may be mixed to exhibit more variations.

According to an embodiment of the present application, the pH sensitive indicator may be manufactured by mixing one or more, two or more, three or more, or four or more of Thymol Blue (Thymol Blue), Methyl Red (Methyl Red), Bromothymol Blue (bromthymol Blue), Phenolphthalein (Phenolphthalein), Phenol Red (Phenol Red), and Bromocresol green (bromocrasol green), and may be selectively combined to reflect various states of the product. Alternatively, two or more, or three or more, or four or more may be mixed to exhibit more variations.

According to another embodiment of the present application, the pH sensitive indicator may be manufactured by mixing four pH color changing dyes, and may be manufactured by mixing thymol blue, methyl red, bromothymol blue, and phenolphthalein.

Thymol blue is red at pH below 2, yellow in the interval 2< pH <7 and blue at pH above 7. Methyl red is red at pH less than 5 and yellow at pH greater than 5.

Bromothymol blue is yellow at pH less than 6 and blue at pH greater than 6. Phenolphthalein is colorless in the interval 0< pH <8, pink in the interval 8< pH <10, and purple at pH > 10.

As described above, since the pH color-changing dye is changed into only two or three colors according to the pH interval, various states of the product cannot be expressed, but when the pH sensitive indicator is manufactured by mixing two or more, three or more, or four or more pH color-changing dyes, the color may be changed differently according to the pH interval.

According to an embodiment, the content of thymol blue may be 0.1% to 10%, the content of methyl red may be 0.1% to 10%, the content of bromothymol blue may be 0.1% to 10%, and the content of phenolphthalein may be 0.1% to 10%, based on the total content of the pH-sensitive indicator. Each content may vary in various ways depending on the nature of the material of the product displayed, the content of the product, and the color displayed by the indicator layer.

According to another embodiment, when 0.01g of thymol blue, 0.02g of methyl red, 0.33g of bromothymol blue and 0.19g of phenolphthalein are mixed to make a pH sensitive indicator, the pH sensitive indicator is red in the interval of 1< pH <2, orange in the interval of 2< pH <4, yellow in the interval of 4< pH <5, green in the interval of 6< pH <7, and blue and purple in the interval of pH greater than 7.

As such, since the pH sensitive indicator according to the embodiment of the present application is manufactured by mixing a plurality of pH-changing dyes, the color may be variously changed according to the change of pH, and thus, various expressions may be made according to the state of the product.

According to an embodiment of the present application, the pH sensitive ink composition may include a non-color changing ink composition. The non-color-changing ink composition may further include a pH non-sensitive color ink composition and/or a white ink composition. The pH non-responsive colored ink composition and/or the white ink composition may be a single layer formed of a single composition, and the pH responsive indicator and the color changing ink composition formed of the color changing ink composition may include a non-color changing ink composition layer formed of the non-color changing ink composition, respectively.

Thus, visibility can be improved by mixing the color-changing ink composition and the non-color-changing ink composition. Further, when the indicating layer including the color-changing ink composition and the non-color-changing ink composition is formed, by using the non-color-changing ink composition, the amount of the color-changing ink used can be reduced in the process of forming the indicating layer, and thus a cost reduction can be expected.

A white ink composition may be used to clearly show the color of the indicating layer, thereby increasing the visibility of the color change when the color of the indicating layer changes. The white ink composition is formed of a composition including a white ink, and one or more pigments selected from inorganic pigments and white organic pigments, such as titanium dioxide, zinc oxide, Lithopone (Lithopone), zinc sulfide (ZnS), lead white, antimony oxide (antimony shite), and the like, may be used for the white ink composition.

Any non-discoloring ink composition may be used as long as its color does not change by the color change factor to be confirmed using an indicator for food, and specifically, any non-discoloring ink composition may be used as long as its color does not change by the color change factor of the color-changing ink composition. More specifically, the non-color-changing ink composition may use a pigment that does not change color due to a change in pH.

The kind of the non-color-changing ink composition is not particularly limited, but, for example, a non-color-changing ink composition may be selected which is not discolored by external environmental factors and, when combined with an ink used as a color-changing ink composition, can make the color change of the mixed color more noticeable to increase visibility. For example, the non-color-changing ink composition may use at least one pigment realizing white, yellow, red, brown, green, blue, black, gold, and silver colors or a mixed color thereof, alone or in combination.

The content of the pigment in the ink composition for forming the indicating layer, for example, the color-changing ink composition, the non-color-changing ink composition, or the mixed composition of the color-changing and non-color-changing inks, may be variously formed. For example, pigments may be included such that the color-changing ink composition is from 1 wt% to 10 wt% and the non-color-changing ink composition is from 0.05 wt% to 2 wt%, based on the total weight of the ink composition.

For example, when the composition of the pigment is included in the ink composition in the above-described interval and the indicating layer is formed by mixing the color-changing ink composition and the non-color-changing ink composition, although the degree of change of the indicating layer is reduced by reducing the content of the color-changing ink composition, the visibility of the indicating layer may be increased compared to when the non-color-changing ink composition is not used. More specifically, in the indicating layer in which the color-changing ink composition and the non-color-changing ink composition are mixed, since conditions such as color, brightness, and saturation of the initial indicating layer are easily compared with conditions such as color, brightness, and saturation of the final indicating layer, it is possible to easily recognize the change of the indicating layer.

The dissolving ink may dissolve the pH responsive indicator, and the pH responsive indicator is dissolved in the dissolving ink while being stirred with the dissolving ink. The dissolving ink may dissolve the pH-changing dye and the pH-sensitive indicator, may have physical properties capable of printing, and may be composed of a plurality of transparent materials capable of expressing inherent colors of the ink composition, and may include both thermosetting and UV-curing.

The dissolving ink may include an ethanol type urethane resin, and more particularly, may include, for example, an ethanol type urethane resin, a wax used as a lubricant, an antistatic agent to prevent static electricity, an additive including a defoaming agent to prevent air generation, and an ethanol solvent, and the reason why the ethanol type urethane resin is used is because a pH discoloration dye is dissolved in ethanol.

Here, according to an embodiment, the dissolved ink may include 25 to 45% by weight of a resin, 1 to 3% by weight of an additive, and 52 to 74% by weight of a solvent, and a weight ratio of the pH sensitive indicator with respect to the weight of the dissolved ink may be 0.4 to 5% when the pH sensitive indicator is stirred in the dissolved ink. According to one embodiment, the dissolving ink may consist of 35g of resin, 0.5g of wax, 1g of antistatic agent, 1g of defoamer, and 62.5g of ethanol.

When the color change of the color-changing ink composition is insufficient, it is difficult to recognize the color change from the outside, and conversely, when the color change of the color-changing ink composition is too sensitive, it is difficult to display a target color according to the state of a product.

However, according to an embodiment, when the weight ratio of the pH sensitive indicator to the weight of the dissolved ink is 0.4% to 5%, it is possible to prevent occurrence of insignificant color change of the ink composition or excessive sensitivity of the color change of the ink composition, and thus to improve visibility.

However, the content ratio of the dissolved ink and the weight ratio of the pH sensitive indicator to the weight of the dissolved ink are not limited thereto, and may vary depending on the dissolved ink and the pH-changing dye used.

The pH sensitive color change ink composition according to an embodiment of the present application may be color-changed into a plurality of colors according to a change in pH by the pH sensitive indicator, and a gas may induce a pH change of the pH sensitive color change ink composition. The color of the pH sensitive color change ink composition may change according to a change in pH when the composition adsorbs a gas.

The adsorbent compound can adsorb gases and be agitated with the dissolved ink to form the final ink composition. The adsorption compound is a chemical composition that changes from acidic to basic or from basic to acidic by sensing a gas, and various substances can be used as long as the pH can be changed according to the gas.

Here, the pH sensitive color change ink composition according to an embodiment of the present application includes the pH sensitive indicator, the dissolved ink, and the adsorption compound, and a mixing order of the pH sensitive indicator, the dissolved ink, and the adsorption compound is not limited.

Specifically, the adsorption compound may be stirred in the dissolution ink after the pH responsive indicator is stirred in the dissolution ink, and the pH responsive indicator may be stirred in the dissolution ink after the adsorption compound is stirred in the dissolution ink. In addition, after the pH sensitive indicator and the adsorption compound are stirred, they may be stirred in the dissolving ink.

The adsorbing compound may change the pH of the color-changing ink composition while adsorbing the Volatile compound, more specifically, may change the pH of the color-changing ink composition by reacting with a Volatile gas such as carbon dioxide, ammonia, acetic acid, Total Volatile basic amine (Total Volatile basic amine), Volatile basic nitrogen (Volatile basic nitrogen), or H2S, and more specifically, the component changing the pH in the present invention may be carbon dioxide.

The adsorbed compound may be a material that changes the pH of the dissolved ink while stirring with the dissolved ink. Specifically, the adsorption compound may be a material that changes the pH of the dissolved ink in a direction opposite to the direction in which the pH is changed by the reaction of the ink composition.

According to an embodiment, when the adsorbed compound is stirred in the dissolved ink, the pH of the dissolved ink may become alkaline, and when the ink composition reacts with a gas, the pH may become acidic.

The adsorbent compound may be polyethyleneimine. The polyethyleneimine may adsorb carbon dioxide, and is a substance that makes the ink composition alkaline while stirring together with the dissolved ink. The ink composition in which polyethyleneimine is stirred is alkaline, and then becomes acidic as carbon dioxide is adsorbed.

When the adsorption compound, more specifically polyethyleneimine, is stirred in the dissolved ink with the pH-sensitive indicator stirred, the weight ratio of the adsorption compound relative to the weight of the dissolved ink may be 0.5% to 20%, more specifically 0.5% to 15%, more specifically 0.5% to 10%, and the upper limit of the more specific content may be selected from 9.5%, 9%, and 8%, and the lower limit may be selected from 0.5%, 1%, and 2%. More specifically, the weight ratio of the adsorbed compound relative to the weight of the dissolved ink may be 0.5% to 9.5% or 0.5% to 9%.

When the adsorption compound is included within the scope of the present invention, more specifically equal to or less than 15%, more specifically equal to or less than 10%, the stickiness during printing can be minimized, and thus the process can be applied without a separate chemical or mechanical treatment.

When the product is a sepia, the weight ratio of the adsorption compound to the weight of the dissolved ink may be 5% to 20%, and in the above range, a target color may be recognized according to the state of the sepia.

However, the weight ratio of the adsorption compound to the weight of the dissolved ink is not limited thereto, and the weight ratio of the adsorption compound may vary according to the target pH of the initial ink composition.

[ TABLE 1 ]

Table 1 above shows the kinds of the pH sensitive indicator, the dissolved ink, and the adsorption compound for changing the color of an ink composition by sensing carbon dioxide by a pH sensitive color change ink composition according to an embodiment of the present application.

The pH sensitive color change ink composition according to an embodiment of the present application described above may change the color of the ink composition by sensing carbon dioxide, and may be used in a fanciful packaging material. As the cookies in the cookie wrapper mature, carbon dioxide is produced. Therefore, the degree of ripeness can be known by changing the pH of the color-changing ink composition as it adsorbs carbon dioxide.

When the color-changing ink composition is applied to the xinqi packaging material, the color-changing ink composition may be printed on the first film or the packaging material container for use. In order to print the ink composition on the first film or the packaging material container, it is necessary to adjust the viscosity of the color-changing ink composition, and for this purpose, the color-changing ink composition may be diluted with a diluent.

Specific examples of the present application are explained below.

[ TABLE 2 ]

Table 2 above shows the kinds and content ratios of the pH sensitive indicator, the dissolved ink, and the adsorption compound for changing the color of an ink composition by sensing carbon dioxide by a color-changing ink composition according to an embodiment of the present application.

Referring to tables 1 and 2, the pH sensitive indicator may be manufactured by mixing a pH color changing dye consisting of thymol blue, methyl red, bromothymol blue, and phenolphthalein, and may be manufactured by mixing thymol blue, 0.02g of methyl red, 0.33g of bromothymol blue, and 0.19g of phenolphthalein.

Referring to table 2 above, the weight of the diluent is preferably 45% to 55% (or 50%) relative to the weight of the dissolved ink, and is mixed with the ink composition. The diluent may use propylene glycol methyl ether acetate (PMA) or ethanol, but is not limited thereto, and various diluents may be used.

The color-changing ink composition can change color by adsorbing carbon dioxide generated according to the degree of ripeness of the cookies, and thus the state of the cookies can be determined.

Referring to tables 1 and 2, in order to determine the state of a magic note by the color-changing ink composition, the pH-sensitive indicator may be manufactured by mixing four kinds of the pH-changing dyes consisting of thymol blue, methyl red, bromothymol blue, and phenolphthalein, and the dissolving ink may be manufactured from an ethanol type urethane resin, wax, an antistatic agent, and an antifoaming agent.

In addition, in order to change the pH of the color-changing ink composition by adsorbing carbon dioxide generated from the cookies, the adsorption compound may be made of polyethyleneimine. Here, the polyethyleneimine makes the color-changing ink composition alkaline while stirring with the dissolved ink, and changes the color of the color-changing ink composition while gradually becoming acidic as it adsorbs carbon dioxide. The polyethyleneimine renders the color-changing ink composition alkaline, in which case the color-changing ink composition may be blue in color.

The color-changing ink composition according to the embodiment of the present application described above shows the kinds and content ratios of the pH sensitive indicator, the dissolved ink, and the adsorption compound for changing the color of the ink composition by sensing carbon dioxide, but is not limited thereto.

In the color-changing ink composition according to the embodiment of the present application, the kind and content ratio of the pH-color-changing dye and the pH-sensitive indicator may vary according to the adsorbed gas, and thus, the kind and content ratio of the dissolved ink and the adsorbed compound may also vary.

[ TABLE 3 ]

Referring to the above table 3, the pH sensitive indicator of the color changing ink composition according to another embodiment of the present application may be manufactured by mixing four kinds of the pH color changing dyes consisting of thymol blue, methyl red, bromothymol blue, and phenolphthalein, or may be manufactured by mixing five kinds of the pH color changing dyes consisting of thymol blue, methyl red, bromothymol blue, phenolphthalein, and bromocresol green.

In addition, the color-changing ink composition according to another embodiment of the present application may include a pigment having a color. The pigment may have a color to improve visibility of the color-changing ink composition, and may be a scarlet pigment as shown in table 3. However, the general pigment is not limited to scarlet and may be composed of various colors capable of improving visibility.

The pigment may be stirred in the dissolved ink in which the pH responsive indicator is stirred, and a weight ratio of the pigment to a weight of the dissolved ink may be 0.05% to 10% when stirred in the dissolved ink in which the pH responsive indicator is stirred. However, the weight ratio of the pigment to the weight of the dissolved ink is not limited thereto, and may vary depending on the pigment, the dissolved ink, and the pH-changing dye used.

As described in the above table 2, when the pH sensitive indicator is manufactured by mixing four kinds of the pH color changing dyes consisting of 0.01g of thymol blue, 0.02g of methyl red, 0.33g of bromothymol blue, and 0.19g of phenolphthalein, if the adsorption compound adsorbs carbon dioxide generated by the symplectic to change the pH of the color changing ink composition, the color changing ink composition may be red at a pH equal to or less than 2, orange in a pH range of 2 to 4, yellow in a pH range of 4 to 5, green in a pH range of 5 to 7, and blue in a pH range of equal to or more than 7.

In this case, the color-changing ink composition exhibits a first color (blue) in a range of pH equal to or greater than 7, a second color (red) in a range of pH equal to or less than 2, a third color in a range of pH 2 to 7, or changes color into two or more colors (orange, yellow, and green) different from the first color and the second color. (Here, the color is prevented from changing in the interval of pH 7 or more by phenolphthalein so that the color may not change and remain constant during the Xinchi immature period.)

[ TABLE 4 ]

	Immature stage	Stage of maturity	Over-mature period
				Acidity (conversion based on lactic acid)	0.2～0.6％	0.6～1.1％	1.1～1.3％
pH	4.6 or higher	4.6～4.2	4.2 or less
				Color change	Blue → green	Green-yellow	Yellow ← red

Table 4 above shows that the pH according to the cookie ripening degree at the composition of composition 6 according to table 3, the pH at the cookie immature stage may be equal to or greater than 4.6, the pH at the cookie mature stage may be 4.2 to 4.6, and the pH at the cookie mature stage may be equal to or less than 4.2. According to an embodiment of the present application, the color-changing ink composition according to compositions 1 to 4 may change color according to the pH of the pungent-curie ripening degree as described above.

Specifically, the color-changing ink composition, which becomes alkaline due to polyethyleneimine, is blue, and becomes acidic and changes color while adsorbing carbon dioxide generated by the octane. Referring to table 4, the color-changing ink composition exhibited a first color (blue) when the cookie was in an immature state, i.e., pH of 4.6 or more, and exhibited a second color (red) when the cookie was in an immature state, i.e., pH of 4.2 or less.

The pungent pH at the stage of maturity between the immature stage and the mature stage is 4.2 to 4.6, in which case the color-changing ink composition may take a third color or change color into two or more medium colors (green-yellow) different from the first color and the second color.

That is, the color-changing ink composition appears blue (first color) when the cookie is in an immature stage, and the color-changing ink composition appears green when its pH falls to less than 4.6 when the cookie is in a mature stage. Thereafter, the color-changing ink composition may change color to two or more colors during the cookie prime period, and thus, may change from green to yellow at a pH of 4.6 to 4.2 in the cookie. When the cookie is in an over-ripening period, i.e., the pH is equal to or less than 4.2, the color-changing ink composition in yellow may turn red again (second color).

As described above, as the color of the color-changeable ink composition changes, the degree of ripeness of the legend is known. The part of the curious maturity that is meaningful to the user may be the stage of maturity (pH of 4.2 to 4.6), and thus, the state of the stage of maturity may be subdivided and notified to the user. To this end, the color-changing ink composition may change color into two or more colors during the simmery prime time.

Here, the pH change region of the maturation period and the maturation period may be narrower than that of the immature period. The color-changing ink composition according to the embodiment of the present application forms a pH sensitive indicator by mixing a plurality of pH color-changing dyes to make the color of the color-changing ink composition under the above-mentioned conditions.

However, the color-changing ink composition is not limited to changing color in the above pH range, the pH range in which the color-changing ink composition changes color may be changed as needed, and the pH range may be changed by changing the kind and mixing ratio of a plurality of pH color-changing dyes. For example, since the maturity range and the pH interval may be different according to the components and composition ratio of the fermented food, the composition of the ink composition may be differently adjusted according to the fermented food.

That is, the color-changing ink composition according to the embodiment of the present application may exhibit a first color in a pH of a first interval, exhibit a second color in a pH of a second interval, and exhibit a third color or change color into two or more colors different from the first color and the second color in a pH of a third interval between the pH of the first interval and the pH of the second interval.

Hereinafter, a pH sensitive indicator label (200) and a packaging material (300) manufactured by using the pH sensitive color change ink composition according to an embodiment of the present application will be described in detail.

The pH sensitive color changing ink composition layer (100) used as will be described below may be a layer formed by using the above pH sensitive color changing ink composition. The pH sensitive color changing ink composition constituting the pH sensitive color changing ink composition layer (100) is the same as the above described pH sensitive color changing ink composition, and thus, no further description is given.

The laminate film for pH-sensitive indication including the first film, the pH-sensitive color-changing ink composition layer, and the second film may be in the form of a label or a packaging material.

In the present invention, the packaging material is in a form that may include contents, the form is not limited, but may be, for example, in a pouch form, and includes the first film and the second film according to the present invention, and the pH sensitive color change ink composition means a form including at least a portion in which partial color change is to be confirmed in the packaging material. Even in the form of a packaging material, the composition applied with all the labels to be described below can be applied.

Referring to fig. 1(a) and 1(b), a pH sensing type indicator label (200) using a pH sensing type color change ink composition according to an embodiment of the present application includes a pH sensing type color change ink composition layer (100), a first film (210), and a second film (230). Since the pH sensitive color changing ink composition constituting the pH sensitive color changing ink composition layer (100) has been described above, a detailed description thereof will be omitted.

The first film (210) may be a barrier film that blocks inflow of gas, and may be made of polyethylene terephthalate; (polyethylene terephthalate: PET), Nylon (Nylon), and a transparent deposition film. The color-changing ink composition layer (100) may be formed on the first film (210), and the color-changing ink composition layer (100) may be formed by printing a color-changing ink composition on the first film (210).

When the color-changing ink composition layer (100) is formed by printing a color-changing ink composition on the first film (210), the color-changing ink composition layer (100) may be formed by printing a color-changing ink composition toward a product.

When gas flows into the color-changing ink composition layer (100) from the outside of the product, the color of the color-changing ink composition layer (100) may be changed by the gas outside the product. To prevent this, the first film (210) according to an embodiment may be a barrier film capable of blocking inflow of gas from the outside of the product.

In addition, the first film (210) may be a transparent film since a user needs to recognize the color of the color-changing ink composition layer (100) printed in the first film (210). In fig. 1(a) and 1(b), the first film (210) may be PET, but is not limited thereto, and various films may be used as long as the first film (210) is a barrier transparent film.

Fig. 1(a) shows that the color-changing ink composition layer (100) is printed on the first film (210), and the color-changing ink composition layer (100) may be printed on the first film (210) by a gravure printing method.

Referring to fig. 1(b), the user may recognize the discoloration of the color-changing ink composition layer (100) from the outside of the first film (210), and in order to improve the visibility of the user thereto, a non-color-changing ink composition layer (220) may be formed on the first film (210) on which the color-changing ink composition layer (100) is printed.

According to an embodiment of the present application, an indicator layer including a color changing ink composition layer may be formed on the first film (210). The indicator layer formed on the first film (210) includes a pH sensitive color changing ink composition and a non-color changing ink composition. Here, the pH sensitive color changing ink composition may change in response to pH, and the non-color changing ink composition may not change in response to pH.

Referring to fig. 2(a) to 2(c), the non-color-changing ink composition layer (220) may be formed by printing a white ink composition and/or a color ink composition, and the non-color-changing ink composition layer (220) may be a white ink composition layer (221) and/or a color ink composition layer (222).

The non-color changing ink composition layer (220) may include any one of the white ink composition layer (221) and the color ink composition layer (222), and may include both the white ink composition layer (221) and the color ink composition layer (222).

Further, referring to fig. 1(b) and 3(a), the non-color-changing ink composition layer (220) may be formed on one surface side of the second film (230) with respect to the color-changing ink composition layer (100), and may be formed on one surface side of the first film (210) with respect to the color-changing ink composition layer (100).

Further, referring to fig. 3(b) and 3(c), between the first film (210) and the second film (230), the color ink composition layer (222) -the color-changing ink composition layer (100) -the white ink composition layer (221) may be sequentially disposed, and the white ink composition layer (221) -the color-changing ink composition layer (100) -the color ink composition layer (222) may be sequentially disposed.

Further, according to another embodiment of the present application, the indicator layer of the first film (210) may be formed by alternating at least one pH sensitive color changing ink composition and at least one non-color changing ink composition on one surface of the first film (210).

The colored ink composition layer (222) may be a complementary color ink composition layer of a color displayed by the pH sensitive color changing ink composition layer (100), an ink composition layer of an initial color displayed by the color changing ink composition layer (100), or an ink composition layer of a finished color displayed by the color changing ink composition layer (100).

The color of the complementary color ink composition layer may be a complementary color of colors intended to increase visibility of a user among colors of the color-changing ink composition layer (100) that vary according to pH. Specifically, when it is intended to increase visibility of orange among colors of the color-changing ink composition layer (100) varying according to pH to a user, a blue (complementary) ink composition layer may be used, when it is intended to increase visibility of green, a violet (complementary) ink composition layer may be used, and when it is intended to increase visibility of yellow, a dark blue (complementary) ink composition layer may be used.

The ink composition layer of the initial color displayed by the color-changing ink composition layer (100) may have a color before being changed in color by the reaction of the color-changing ink composition layer (100) with gas. As mentioned above, the pH of the colour changing ink composition may be changed by stirring the adsorbed compound in the dissolved ink before the colour changing ink composition layer (100) reacts with the gas.

For example, when polyethyleneimine as the adsorption compound is stirred in the dissolved ink, the color-changing ink composition may turn blue while becoming alkaline. (thereafter, as carbon dioxide is adsorbed, the alkalinity becomes acidic, and thus, the color of the color-changing ink composition layer (100) changes).

The ink composition layer of the initial color displayed by the color-changing ink composition layer (100) may be a color before being changed in color by the reaction of the color-changing ink composition layer (100) with gas, and when polyethyleneimine is used, the ink composition layer of the initial color displayed by the color-changing ink composition layer (100) may be blue.

When the ink composition layer of the initial color displayed by the color-changing ink composition layer (100) is used, although the change of the color may not be sensed before the color-changing ink composition layer (100) reacts with the gas, the gradual change of the color may be confirmed, and thus, there is an advantage in that the visibility of the user may be improved.

The ink composition layer of the finished color displayed by the color-changing ink composition layer (100) may be a color that is not changed by gas any more after the color-changing ink composition layer (100) is changed in color by reaction with gas. For example, when the color-changing ink composition layer (100) changes color by adsorbing pungent carbon dioxide, the color of the color-changing ink composition layer (100) may be maintained uniformly red when it is below a predetermined interval of pH.

The finished color displayed by the color-changing ink composition layer (100) may be red, and thus, the finished color displayed by the color-changing ink composition layer (100) may be a color that is no longer changed by gas.

The second film (230) may be laminated to the first film (210) to cover the pH-sensitive color-changing ink composition layer (100) formed on the first film (210). Referring to fig. 1(a) and 1(b), the second film (230) may be disposed on a side of the color-changing ink composition layer (100) facing the product, and the second film (230) may be a porous film through which gas can pass in order for gas generated from the product to reach the color-changing ink composition layer (100).

The second film (230) may be composed of any one of Tyvek (Tyvek), Linear low-density polyethylene (LLDPE), Polyethylene (PE), cast polypropylene film (CCP), and porous film, but is not limited thereto, and various films may be used as long as gas can pass therethrough. Here, the second film (230) formed to be porous is not only porous but also gas-permeable, and may be various films as long as gas can pass through.

The second film (230) may be a white film or a colored film, and visibility may be improved by it. Here, the colored film may be composed of a complementary color film of a color displayed by the color-changing ink composition layer (100), a film of an initial color displayed by the color-changing ink composition layer (100), or a film of a finished color displayed by the color-changing ink composition layer (100).

The color of the complementary color film may be a complementary color of colors intended to increase visibility of a user among colors of the color-changing ink composition layer (100) that vary according to pH. Specifically, according to an embodiment, when it is intended to increase visibility of orange among colors of the color-changing ink composition layer (100) varying according to pH to a user, a blue (complementary color) film may be used, when it is intended to increase visibility to green, a violet (complementary color) film may be used, and when it is intended to increase visibility to yellow, a dark blue (complementary color) film may be used.

The film of the initial color displayed by the color-changing ink composition layer (100) may have a color before being changed in color by the reaction of the color-changing ink composition layer (100) with gas. As mentioned above, the pH of the color changing ink composition layer (100) may be changed by stirring the adsorbed compound in the dissolved ink before the color changing ink composition layer (100) reacts with the gas.

For example, when polyethyleneimine as the adsorption compound is stirred in the dissolved ink, the color-changing ink composition layer (100) may turn blue while becoming alkaline. (thereafter, as carbon dioxide is adsorbed, the alkalinity becomes acidic, and thus, the color of the color-changing ink composition layer (100) changes).

According to an embodiment, the film of the initial color displayed by the color-changing ink composition layer (100) may be a color before being changed in color by the reaction of the color-changing ink composition layer (100) with gas, and when polyethyleneimine is used, the film of the initial color displayed by the color-changing ink composition layer (100) may be blue.

When the film of the initial color displayed by the color-changing ink composition layer (100) is used, although the change of the color may not be sensed before the color-changing ink composition layer (100) reacts with the gas, the gradual change of the color may be confirmed, and thus, there is an advantage in that the visibility of the user may be improved.

The film of the finished color displayed by the color-changing ink composition layer (100) may be a color that is not changed by gas any more after the color-changing ink composition layer (100) is changed in color by reaction with gas. When the color-changing ink composition layer (100) changes color by adsorbing pungent carbon dioxide, the color of the color-changing ink composition layer (100) may be maintained uniformly as red when the pH of the gas is lower than the pH of the predetermined interval.

According to an embodiment, the finished color displayed by the color-changing ink composition layer (100) may be red. In this way, the finished color film displayed by the color-changing ink composition layer (100) may have a color that is no longer changed by the gas.

Further, the second film (230) may be composed of a transparent film. When a white ink composition or a color ink composition is printed on the first film (210), the second film (230) may be composed of a transparent film in order to prevent the second film (230) from mixing with the color of the white ink composition or the color ink composition.

Referring to fig. 4(a) and 4(b), the second film (230) may be laminated on the first film (210) on which the color-changing ink composition layer (100) is printed, by an adhesive or bonding agent (231), and the second film (230) may be laminated to the first film (210) after the adhesive or bonding agent (231) is coated on the second film (230). As the adhesive or binder (231), a polyurethane-based binder may be used, and various adhesives or binders may be used as long as the first film (210) and the second film (230) on which the color-changing ink composition layer (100) is printed may be laminated.

According to an embodiment of the application, the indication layer may further comprise a white ink composition on one surface facing the glue or adhesive (231), and the step of bonding the first film (210) and the second film (230) may comprise bonding the first film (210) and the second film (230) such that the white ink composition layer (221) is in contact with the glue or adhesive (231). The pH sensitive indicator label (200) using a pH sensitive color change ink composition according to another embodiment of the present application may be used after a release paper is attached to the second film (230) by an adhesive or a bonding agent after the second film (230) is laminated to the first film (210). Referring to fig. 5, a packaging material (300) using a pH sensitive color change ink composition according to an embodiment of the present application includes a label (200), a container (310), and a through hole (311).

The label (200) is the same as the above-described pH sensing type indicator label (200) using the color-changing ink composition according to an embodiment of the present application, and the label (200) has been described above, so a detailed description thereof will be omitted.

The container (310) has a product inserted therein and has an inner space into which the product (320) can be inserted. The through hole (311) is a hole through the container (310) in an area not in contact with the product (320).

Referring to fig. 5, when the product (320) is inserted into the container (310), the product (320) can be kept in a lower portion of the container (310). The through hole (311) passes through the container (310) in a portion not in contact with the product (320), and may be formed at an upper portion of the container (310) so as not to be in contact with the product (320).

The through-hole is a passage through which a laminated film including the pH-sensitive color-changing ink composition can contact a gas generated from the contents over time, and more particularly, when the laminated film is in the form of a label, the hair product can respond to any material of the surface of a packaging material to which the label is applied due to the presence of the through-hole. The shape thereof is not limited as long as the gas can move, and may be linear, circular, angular, or the shape of a figure to be expressed. In the case of a packaging material, for example, inserted into a bag instead of a label, through-holes as passages through which gas can come into contact in various ways may be formed in the film inside the packaging material.

The label (200) may cover the through hole (311) from the outside of the container (310) and be attached, and the label (200) may be attached on the container (310) by an adhesive or bonding agent (312).

As described above, when the label (200) is attached to the container (310) while covering the through hole (311), gas generated from the product (320) may move to the label (200) through the through hole (311), and the color-changing ink composition layer (100) included in the label (200) may adsorb the gas to change color according to pH, as shown in fig. 5. When the through hole (311) is used, the color of the label (200) is changed by gas even when the label (200) is located at the portion of the container (310) without contacting the product (320). Hereinafter, the effect of the through hole (311) will be described.

To describe the effect of the via holes (311), a color-changing ink composition was manufactured with the composition of table 5 below.

[ TABLE 5 ]

After printing a color-changing ink composition layer on a 12 μm PET film (first film) and drying, a white ink composition was printed and dried, and a second film was attached after coating an adhesive. Thereafter, a gas sensing type pH indicating label is manufactured by coating an adhesive and attaching a release paper.

After the tags were manufactured, a magic storage test was performed on the tags.

Specifically, after the pH sensitive indicator label was attached to a pouch including 400g of a cookie having a through hole, a test was performed at 15 ℃, and the result is shown in fig. 7.

Referring to fig. 7, since the container is manufactured by attaching the label to the through-hole, it can be seen that the color change occurs only at a portion connected to the through-hole. As described above, the color change occurs only at the portion connected to the through-hole, and thus the visibility of the color change is improved.

Hereinafter, the effect of the non-color-changing ink composition layer formed as the color ink composition layer will be described. To illustrate the effect of the color ink composition layer, in the examples, 100 parts by weight of a polyurethane-based binder, 2 parts by weight of bromothymol blue, and 8 parts by weight of polyethyleneimine were first stirred with ethanol as a solvent to manufacture a pH sensitive color change ink composition.

Then, a colored ink composition layer of yellow (non-color-changing ink composition layer) was printed on the 12 μm PET film (first film) by a 175 gravure printing method, and then dried. The color-changing ink composition manufactured as above was printed on the PET film on which the colored ink composition layer (non-color-changing ink composition layer) was printed by a 175 gravure printing method, and then dried. A white ink composition layer was printed on the ink layer formed as above and dried to make a label.

In order to compare the effects of the colored ink composition layer, in the comparative example, a label was produced in the same manner except for the portion where the colored ink composition layer was formed.

As described above, after the tags according to the examples and the tags according to the comparative examples were manufactured, the magic storage test was performed by the tags. Specifically, after the labels according to the examples and comparative examples were attached to the bags having through holes including 400g of cookies, the test was performed under the condition of 15 deg.c, and the results thereof are shown in fig. 8.

Referring to fig. 8, it can be confirmed that the example using the colored ink composition layer improves visibility as compared to the comparative example not using the colored ink composition layer. Specifically, it can be seen that the example of (b) of fig. 8, in which the color-changing ink composition + the color ink composition (yellow) is printed on the back side, is printed more clearly (the boundary of the color-changed portion is printed more clearly) and the visibility is improved, as compared to the comparative example of (a) of fig. 8, in which the color-changing ink composition is used alone.

Referring to fig. 6, a packaging material (300) using a color-changing ink composition according to another embodiment of the present application is to directly print a color-changing ink composition layer (100) on a container (310), and may include the container (310) and a pH-sensitive color-changing ink composition layer (100).

The container (310) has a product inserted therein and has an inner space into which the product (320) can be inserted, and referring to fig. 4, the pH sensitive color changing ink composition layer (100) may be printed in a region of the inner side of the container (310) not in contact with the product (320).

The pH sensitive packaging material (300) using the color-changing ink composition according to another embodiment of the present application may apply all the compositions and features of the label (200) using the color-changing ink composition according to an embodiment of the present application, and in the label (200), the compositions and features of the label (200) may be applied by changing the first film (210) into the container (310).

Specifically, a packaging material (300) using a color-changing ink composition according to another embodiment of the present application may further include a second film (230), and the second film (230) may be laminated to the container (310) such that a color-changing ink composition layer (100) is disposed between the container (310) and the second film (230).

In addition, the second film (230) may be composed of a white film or a colored film (a complementary color film of a color displayed by the color-changing ink composition, a film of an initial color displayed by the color-changing ink composition, or a film of a finished color displayed by the color-changing ink composition).

Meanwhile, the container (310) on which the color-changing ink composition layer (100) is printed may be printed with a white ink composition or a color ink composition (a complementary color ink composition of a color displayed by the color-changing ink composition, an ink composition of an initial color displayed by the color-changing ink composition, or an ink composition of a complete color displayed by the color-changing ink composition), and the second film (230) may be composed of a transparent film. In addition, the second film may be laminated to the container after applying an adhesive or binder to the container on which the color-changing ink composition is printed.

Further, according to an embodiment, a through hole may be formed inside a portion of the container including the color-changing ink composition layer (100).

The magic packing material using the color-changing ink composition according to the example of the present application uses the packing material using the color-changing ink composition according to the example of the present application, and the product packed in the container is a magic.

A cookie packaging material using a color changing ink composition according to an embodiment of the present application may include a container having a cookie inserted therein, and an ink composition in a region of the container not in contact with the cookie. The method of including the ink composition in the container may use a label in the same manner as the above-described method, and the ink composition may be directly printed on the container. (the ink composition, label and packaging material applied to the magic packaging material using the color-changing ink composition according to the examples of the present application are the same as described above, and thus detailed description thereof will be omitted.)

The magic packing material using the color-changing ink composition according to the embodiment of the present application changes the color of the ink composition by adsorbing carbon dioxide generated from the magic, and may show the state of the magic to a user by sensing carbon dioxide generated from the state of the root magic.

To this end, the xinqi packaging material using the color-changing ink composition according to the embodiment of the present application may be mixed with pH color-changing dyes of two or more of thymol blue, methyl red, bromothymol blue, phenolphthalein, phenol red, and bromocresol green, and the adsorption compound may be polyethyleneimine.

The final ink composition is manufactured by stirring and dissolving in the dissolving ink a pH sensitive indicator manufactured by mixing two or more pH-changing dyes of thymol blue, methyl red, bromothymol blue, phenolphthalein, phenol red, and bromocresol green, and stirring polyethyleneimine. Here, the ink composition may be rendered alkaline by stirring the polyethyleneimine.

The ink composition may have alkalinity of pH 10 or more by polyethyleneimine, and in this case, the ink composition is blue. When the legend generates carbon dioxide according to the legend state, the ink composition becomes acidic by lowering the pH by adsorbing carbon dioxide by polyethyleneimine as an adsorbing compound, and the pH sensitive indicator (pH color changing dye) reacts according to the pH to change color, thereby showing the legend state changing from basic to acidic.

The color-changing ink composition according to an embodiment of the present application and the label and packaging material using the same described above have the following effects.

The pH sensitive color-changing ink composition according to an embodiment of the present application and the label and packaging material using the same may manufacture the pH sensitive indicator by mixing a plurality of pH color-changing dyes such that the ink composition may change various colors according to a change in pH, thereby informing a consumer of various states of a product.

In addition, the pH sensitive color change ink composition and the label and packaging material using the same according to the embodiments of the present application can discriminate the state of the product by the gas generated from the product, so that the state of the product can be determined in a non-contact manner with the product.

As described above, the present application is described in detail with reference to the embodiments, and the present application is not limited to the above-described embodiments, and various modifications may be made without departing from the scope of the application. Therefore, the true technical protection scope of the present application should be subject to the technical ideas of the appended claims.