KR20050069542A - A process of dyeing on polypropylene fiber by using basic dye and the polypropylene fiber dyed thereof - Google Patents

Abstract

The present invention relates to a method for dyeing a polypropylene fiber using a basic dye and to a polypropylene fiber dyed therefrom, wherein the polypropylene fiber is irradiated with electron beams, gamma rays, and plasma in the air and treated with a chemical agent to bind the basic dye. After introducing the functional group, that is, the dye seat, the functional group and the basic dye are dyed by ionic bonding to expand the function of the polypropylene fiber so that it can be used as a garment fiber and at the same time to produce a dyeing product of uniform quality. To get it.

To this end, the present invention comprises the steps of introducing an epoxy group as the primary active species to the polypropylene fiber by reaction with oxygen in the air as the radiation to the polypropylene fiber in the air; The epoxy group is reacted with one of chlorosulfonic acid, 3- (chlorosulfonyl) benzoic acid, 4- (chlorosulfonyl) benzoic acid, and phosphoric acid, and dyes such as sulfone groups, carboxyl groups, and phosphoric acid groups that are dissociated with anions to the polypropylene fibers, respectively. Introducing a seat; And dyeing the polypropylene fiber by ion-bonding the basic dye having a cation with the dye seat.

Description

Process for dyeing on polypropylene fiber by using basic dye and the polypropylene fiber dyed

The present invention relates to a method for dyeing a polypropylene fiber using a basic dye and to a polypropylene fiber dyed therefrom. Specifically, the polypropylene fiber is irradiated with electron beams, gamma rays, and plasma in air and treated with a chemical agent to give basic After introducing a functional group capable of bonding with dyes, that is, a dyed seat, the functional groups and basic dyes are dyed by ionic bonding, thereby expanding the function of the polypropylene fiber so that it can be used as a garment for clothing and with uniform quality. It relates to a dyeing method of polypropylene fiber using a basic dye to obtain a dyeing product and to a polypropylene fiber dyed therefrom.

In general, polypropylene fibers have a smaller specific gravity than other fibers, which are light, non-static, non-burning, and difficult to grow, making them hygienic. In addition, due to the low thermal conductivity, it is not only excellent in thermal insulation, but also has good chemical resistance, high strength, and good mechanical properties.

However, the polypropylene fiber is a representative hydrophobic fiber composed only of carbon and hydrogen and does not have a dye seat that can be combined with a dye. Therefore, it is impossible to dye any dye using a conventional dyeing method. There is a problem in maintaining the function as a fiber, such as very difficult.

Accordingly, in order to improve the above problems, a study has been attempted to improve the dyeability through the production of a new type of polypropylene fiber and the modification of the existing polypropylene fiber.

In other words, in the production of a new type of polypropylene fiber, a method of introducing an additive such as halogen aluminum, pigment, water, or the like, or adding a monomer having a polar group in the production of polypropylene fiber is being carried out. Because it is not a dyeing method using only, the study was limited.

In addition, as a method for improving the dyeability through the modification of the existing polypropylene, a method of graft copolymerization of monomers having a polar group in polypropylene fibers has been studied, but this is due to the deterioration of physical properties due to radicals generated during graft copolymerization or the polarity of graft copolymerization. There is a problem in terms of uniformity of fiber quality because it is difficult to control the length of the monomer chain constantly.

In addition, the synthesis of new dyes with excellent dyeability and color fastness is required, but there is no known or successful case for the synthesis and development of dyes for polypropylene fibers.

The present invention was developed to solve the above problems, by introducing a functional group of a monomolecular form that can be ion-bonded with basic dye to the pure polypropylene fiber by providing a dye adsorption function to the polypropylene fiber uniform quality It is an object of the present invention to provide a dyeing method of a polypropylene fiber using a basic dye which can be used as a garment for textiles and other textile products and at the same time to obtain a dyed product of the same and a polypropylene fiber dyed therefrom.

In order to achieve the above object, the dyeing method of the polypropylene fiber using the basic dye according to the present invention, and the polypropylene fiber dyed therefrom, reacts with the oxygen in the air as the polypropylene fiber is irradiated in the air. Introducing an epoxy group which is a primary active species into the polypropylene fiber; The epoxy group is reacted with one of chlorosulfonic acid, 3- (chlorosulfonyl) benzoic acid, 4- (chlorosulfonyl) benzoic acid, and phosphoric acid, and dyes such as sulfone groups, carboxyl groups, and phosphoric acid groups that are dissociated with anions to the polypropylene fibers, respectively. Introducing a seat; And dyeing the polypropylene fiber by ion-bonding the basic dye having a cation with the dye seat.

Hereinafter, a method for dyeing a polypropylene fiber using the basic dye of the present invention and a polypropylene fiber dyed therefrom will be described in detail according to the process.

First step: irradiation and introduction of epoxy group

First, a process of introducing an epoxy group by irradiating a polypropylene fiber with radiation using a radiation source such as an electron beam, gamma ray, or plasma.

That is, when the polypropylene fiber is irradiated with radiation such as electron beams, gamma rays, plasma, etc. in air, the radiation is irradiated and a chemical change is generated inside the polypropylene fiber by reaction with oxygen in the air. Epoxy groups are newly formed in polypropylene fibers, the active species with excellent reactivity with other compounds (see Figure 1).

In this case, the irradiation amount (absorption dose) of the electron beam or gamma ray is preferably 10 to 150 kGy (kilologray), preferably 20 to 80 kGy. If the irradiation dose is lower than 10 kGy, the epoxy group as the primary active species is not properly introduced. At high doses of 150 kGy or higher, there is a possibility that the physical properties such as strength reduction and yellowing of the fiber are lowered.

Here, the irradiation amount (absorption dose) means the amount of energy given to the target material by the incident radiation per unit mass, and this irradiation amount is controlled by adjusting the current value during irradiation, the distance between the irradiation window and the fiber, and the irradiation time. It is possible.

In the case of plasma, the frequency range is set to 60 Hz to 18.56 MHz, and the treatment time is changed to 3 to 15 minutes, preferably 5 to 10 minutes, under the above conditions. If the irradiation time is less than 3 minutes, the amount of primary active species introduced into the salt seat is not effective. If the irradiation time exceeds 15 minutes, yellowing occurs or the texture of the fiber becomes rough. .

As described above, since the epoxy group formed on the polypropylene fiber is rich in reactivity and is easily converted into another type of functional group by reaction with another chemical agent, it is required in the present invention by reacting the epoxy group with another chemical agent in the next step. It is possible to introduce a seated seat.

Step 2: Introduce chemical treatment and dye seat

Subsequently, a sulfone group, a carboxyl group, which is a functional group capable of ion-bonding with a basic dye by reacting an epoxy group introduced into a polypropylene fiber with a chemical agent through radiation of electron beam, gamma ray, plasma, etc. in the first step It is the process of introducing salt seats, such as a phosphate group.

Here, the dye seat is a site where dye can proceed by reacting and combining one molecule with one molecule of dye, that is, a site that can be combined with a dye.

① Sulfone group (-SO ₃ H) introduction process

Chlorosulfonic acid (ClSO ₃ H) is used as a chemical for the introduction of the sulfonic group, and the solvent is methanol, ethanol, N, N-dimethylformamide (Methanol). N, N-dimethylformamide), dimethyl sulfoxide (Dimethylsulfoxide), dimethylacetamide (Dimethylacetamide), benzene (Benzene), 1,4-dioxane (1,4-dioxane) is selectively used.

That is, the sulfonic group is introduced into the polypropylene fiber as the epoxy group introduced into the polypropylene fiber reacts with the chlorosulfonic acid and is converted into a form as shown in FIG. 2.

As the conditions for the sulfonation reaction, the concentration of the chlorosulfonic acid is preferably 0.01 ~ 1M 0.02 ~ 1M, the reaction temperature is preferably 40 ~ 80 ℃ preferably 50 ~ 70 ℃, if the chloro If the concentration of sulfonic acid is less than 0.01M, the amount of sulfonic groups introduced for dyeing is not effective, whereas if it exceeds 1M, yellowing occurs.

When the reaction temperature is lower than 40 ° C., the reaction rate at which the sulfone group is introduced is significantly lowered. On the other hand, when the reaction temperature is higher than 80 ° C., the reaction proceeds at a too fast speed, making it difficult to control the process.

In addition, it is preferable that the reaction time be appropriately selected according to the temperature, but the temperature is preferably about 1 hour at 40 ° C. and about 30 minutes at 80 ° C., and the introduction of sulfone groups is most effective at these times.

The amount of the solvent is preferably about 20 to 50 times based on the weight of the fiber to be treated, which is based on the amount of fiber to be sufficiently immersed in the treatment liquid.

② Carboxyl group (-COOH) introduction process

In order to introduce the carboxyl group (Carboxyl group), 3- (chlorosulfonyl) benzoic acid (3- (Chlorosulfonyl) -benzoic acid: ClSO ₂ C ₆ H ₄ COOH) and 4- (chlorosulfonyl) benzoic acid ( 4- (Chlorosulfonyl) -benzoic acid: ClSO ₂ C ₆ H ₄ COOH), where solvents are methanol, ethanol, N, N-dimethylformamide, dimethylsulfoxide, dimethylacetamide, benzene, 1,4 -Selectively used among dioxane.

That is, the epoxy group introduced into the polypropylene fiber is converted into the form as shown in Figures 3 and 4 by reacting with 3- (chlorosulfonyl) benzoic acid or 4- (chlorosulfonyl) benzoic acid.

 Accordingly, a carboxyl group is introduced into the polypropylene fiber.

The concentration of the chemicals 3- (chlorosulfonyl) benzoic acid and 4- (chlorosulfonyl) benzoic acid is preferably 5 to 10% owf (on the weight of fabric%), if less than 5% owf While the amount of carboxyl groups to be introduced is not sufficient, when the amount exceeds 10% owf, the fiber tends to be stiff.

And, the reaction temperature is preferably 50 ~ 90 ℃ preferably 50 ~ 70 ℃, if it is lower than 50 ℃ the reaction rate is lowered to increase the reaction time, if the higher than 90 ℃ There is not much difference in reaction rate because it is not very effective.

In addition, the reaction time is 1 to 3 hours, preferably 1 to 2 hours. If less than 1 hour, the amount of carboxyl groups to be introduced is insufficient, and if more than 3 hours, the amount of further carboxyl groups is not increased. Therefore, the reaction time may be preferably controlled within 3 hours.

In addition, the amount of the solvent is preferably 20 to 50 times based on the weight of the fiber treated similarly to the sulfone group introduction method.

③ Phosphoric acid group (-PO ₃ H) introduction process

Phosphoric Acid (H ₃ PO ₄ ) is used to introduce the phosphate group.

That is, the epoxy group introduced into the polypropylene fiber is introduced into the polypropylene fiber as it is converted into a form as shown in Figure 5 by reacting with phosphoric acid.

The concentration of phosphoric acid is preferably 50 to 98%, preferably 50 to 85%. If the mixing ratio with water is less than 50%, the reaction in which the epoxy group is converted to the phosphate group by the action of water is suppressed. It is not suitable because it tends to be yellow, and if it exceeds 98%, yellowing may occur.

The reaction temperature is preferably 80 to 120 ° C., preferably 90 to 110 ° C., and the reaction time is 10 to 60 minutes, preferably 15 to 30 minutes. In order to increase the reaction time, there is a hassle, and when the temperature exceeds 120 ℃ yellowing phenomenon occurs in the fiber.

In addition, when the reaction time is less than 10 minutes, the amount of phosphate groups introduced is less, while if it exceeds 60 minutes, the yellowing of the fiber is excessively exceeded 60 minutes is not appropriate.

Thus, the sulfone group, carboxyl group, and phosphate groups introduced into the polypropylene fiber can be easily dissociated into anions, so that the basic dyes can be easily ion-bonded with the basic dye having a cationicity in the next step, so that the basic dye can be dyed to the polypropylene fiber. You lose.

Step 3: dyeing with basic dye

Next, in the second step, a dye is used to dye polypropylene fibers in which salt seats such as sulfone groups, carboxyl groups, and phosphoric acid groups are introduced using a basic dye.

The dyeing conditions in this process are preferably performed at pH4.5 ~ 7, preferably about 6.8, which is weakly acidic. In general, dyeing of basic dyes is carried out under weakly acidic conditions. It is not preferable to set the pH to 7 or more, because there is a possibility of becoming.

In addition, other processes are performed similarly to the dyeing using a conventional basic dye.

Hereinafter, the dyeing method of the polypropylene fiber according to the present invention will be described in more detail with reference to the following examples. However, the following examples are only examples of introducing a sulfone group after irradiation with an electron beam, but this is only one example to help the understanding of the present invention, and the present invention is not limited thereto.

Example 1

(Sulfone group introduction and dyeing amount according to the irradiation amount of electron beam)

In this embodiment, the polypropylene fiber irradiated with electron beam was stained with a basic dye after introducing a sulfone group using chlorosulfonic acid, and the nonwoven fabric produced by Toray Co., Ltd. (weight 120 g / m ² ) was used, and basic blue 12 was used as the dye.

The concentration of the chlorosulfonic acid was fixed at 0.7M, the irradiation amount of the electron beam was changed to 0kGy, 28.2kGy, 42.3kGy, 56.4kGy, 70.5kGy in the order of Samples 1 to 5, respectively, under the same concentration of chlorosulfonic acid The amount of sulfone group introduced according to the amount of electron beam irradiation and the apparent concentration (K / S value) after staining were measured, and a comparison of the increase in dyeing amount according to the amount of sulfone group introduced was shown in Tables 1 and 6 below.

Here, the apparent concentration (K / S value) is a formula used when measuring the concentration of the stained sample indicates that the larger the value is darker.

K / S = (1-R) ² / 2R

K: Absorption (absorption) coefficient of the dye, S: scattering coefficient, R: spectral reflectance.

In addition, the concentration of the dye was fixed at 0.5% owf, the dyeing temperature and time were carried out for 2 hours at a temperature of 90 ℃ each and the pH was adjusted to 6.8.

▶ Experimental condition

   1. Sample: Polypropylene Fiber

   2. Electron beam dose: 0kGy, 28.2kGy, 42.3kGy, 56.4kGy, 70.5kGy

   3. Chemicals for introducing sulfone groups: Chlorosulfonic acid (concentration: 0.7M, 60 ℃ × 30min.)

   4. Solvent: 1,4-dioxane

   5. Dyeing condition: Dye (Basic blue 12, Concentration: 0.5% owf, 90 ℃ × 2hr.)

▶ Experimental Results

According to the results of Table 1 and Figure 6, as the total amount of irradiation of the electron beam increases, the apparent concentration (K / S value) of the dyed sample is increased, pure polypropylene that is not irradiated with the electron beam like sample 1 When the sample was treated with chlorosulfonic acid and dyed under the same conditions as the polypropylene sample irradiated with electron beams, the dye was not stained at all by basic dyes. When dyeing with basic dyes, the amount of dyeing increased as the amount of irradiation of the electron beam increased. This is because the amount of sulfone groups introduced under the same conditions, that is, the amount of salting seat, increased as the amount of electron beam irradiation increased. .

Therefore, the conventional polypropylene fiber (sample 1) is impossible to give color when dyeing with a basic dye, while the polypropylene fiber (samples 2 to 5) into which sulfone groups are introduced after electron beam irradiation is dyed with a basic dye. When satisfactory dyeing proceeded was confirmed.

Example 2

(Sulfone group introduction and dyeing amount according to the concentration of chlorosulfonic acid)

This Example is to measure the introduction of the sulfone group and the dyeing amount at this time according to the concentration of chlorosulfonic acid for the introduction of sulfone groups under the same electron beam irradiation, the sample used in the experiment was the same as in Example 1 but the concentration of chlorosulfonic acid According to the sample 1 to 5 and the experimental results are shown in Table 2 and Figure 7.

▶ Experimental condition

   1. Sample: Polypropylene Fiber

   2. Electron beam irradiation amount: 56.4kGy

   3. Chemicals for introducing sulfone groups: Chlorosulfonic acid (concentrations: 0.03M, 0.07M, 0.2M, 0.7M, 60 ° C × 30min.)

   4. Solvent: 1,4-dioxane

   5. Dyeing condition: Dye (Basic blue 12, Concentration: 0.1% owf, 90 ℃ × 2hr.)

▶ Experiment Result

According to the results of Tables 2 and 7, the apparent concentration of the stained sample increased as the concentration of chlorosulfonic acid increased as a whole, which is the amount of sulfonic groups introduced, that is, dyeing as the concentration of chlorosulfonic acid increased It can be said that the seat is increased, and the amount of sulfonic groups introduced is dependent on the concentration of chlorosulfonic acid.

Therefore, the polypropylene fiber into which the sulfone group was introduced could be confirmed that dyeing proceeded by forming an ionic bond with the basic dye.

As described above, the dyeing method of the polypropylene fiber using the basic dye according to the present invention has been described with reference to the examples, but the present invention is not limited by the embodiments and drawings disclosed herein and those skilled in the art within the scope of the invention. Of course, various modifications may be made.

As described above, according to the dyeing method of the polypropylene fiber using the basic dye of the present invention and the polypropylene fiber dyed therefrom, after irradiating the polypropylene fiber in the air to introduce an epoxy group, a chemical agent is treated therein. By dyeing polypropylene fibers by ionic bonds with cationic basic dyes by introducing salted seats, which are monomolecular functional groups that induce bonds with dyes, acid dyes, basic dyes, reactive dyes, disperse dyes, etc. It is possible to dye polypropylene fiber, which has been difficult to dye with any dye used, so that it can be used as a garment fiber and other textile products and at the same time obtain a uniform quality dyeing product.

In addition, it can be said to be a new method of dyeing, which is completely different from the method of adding other additives to pure polypropylene fibers or introducing a polar monomer in a polymer form such as graft copolymerization.

Claims (9)

Introducing an epoxy group, which is a primary active species, into the polypropylene fiber by reacting with oxygen as the polypropylene fiber is irradiated with radiation selected from electron beams, gamma rays, and plasma in air; Reacting the chlorosulfonic acid with the epoxy group to introduce an anionic sulfonic group into the polypropylene fiber; Dyeing the polypropylene fiber by ion-bonding the basic dye having a sulfonic group with a cationic group, the dyeing method of polypropylene fiber using a basic dye. Introducing an epoxy group, which is a primary active species, into the polypropylene fiber by reacting with oxygen as the polypropylene fiber is irradiated with radiation selected from electron beams, gamma rays, and plasma in air; Reacting the epoxy group with a chemical agent selected from 3- (chlorosulfonyl) benzoic acid or 4- (chlorosulfonyl) benzoic acid to introduce an anionic carboxyl group into the polypropylene fiber; The dyeing method of the polypropylene fiber using a basic dye, characterized in that for dyeing the polypropylene fiber by ion-bonding the basic dye having a carboxyl group and a cationic. Introducing an epoxy group, which is a primary active species, into the polypropylene fiber by reacting with oxygen as the polypropylene fiber is irradiated with radiation selected from electron beams, gamma rays, and plasma in air; Reacting phosphoric acid with the epoxy group to introduce an anionic phosphoric acid group into the polypropylene fiber; Dyeing the polypropylene fiber by ion-bonding the basic dye having a phosphate group and a cationic dye. The method according to any one of claims 1 to 3, The electron beam or gamma ray dyeing method of polypropylene fiber using a basic dye, characterized in that the irradiation amount is 10 ~ 150kGy. The method according to any one of claims 1 to 3, The plasma dyeing method of polypropylene fiber using a basic dye, characterized in that for irradiating for 3-15 minutes at a frequency range of 60Hz to 18.56MHz. The method of claim 1, In the step of introducing the sulfone group in a solvent selected from 20 to 50 times the weight of the fiber, methanol, ethanol, N, N- dimethylformamide, dimethyl sulfoxide, dimethylacetamide, benzene, 1,4-dioxane The temperature of 40 ℃ ~ 80 ℃, 30 minutes to 1 hour polypropylene fiber dyeing method using a basic dye, characterized in that for reacting the chlorosulfonic acid of 0.01M ~ 1M with the epoxy group. The method of claim 2, In the step of introducing the carboxyl group 20 to 50 times the weight of the fiber in one solvent selected from methanol, ethanol, N, N- dimethylformamide, dimethyl sulfoxide, dimethylacetamide, benzene, 1,4-dioxane Basic dye, characterized in that for reacting the epoxy group with one of the 3- (chlorosulfonyl) benzoic acid or 4- (chlorosulfonyl) benzoic acid of 5 to 10% owf for 1 to 3 hours at a temperature of 50 ~ 90 ℃ Method for dyeing polypropylene fiber using. The method of claim 3, Method for dyeing polypropylene fiber using a basic dye, characterized in that for reacting the epoxy group with 50 to 98% phosphoric acid for a temperature of 80 ~ 120 ℃, 10 to 60 minutes in the step of introducing the phosphate group. A polypropylene fiber dyed by the method of any one of claims 1 to 8.