JP2004068170A - Method for forming pattern and dyed fabric - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a new method for forming a pattern in which ozone gas can efficiently be utilized to readily carry out a wastewater treatment under a slight environmental load and the contrast is high. <P>SOLUTION: The method for forming the pattern on a dyed fabric is characterized by including water in the dyed fabric, then bringing the dyed fabric into contact with the ozone gas in a contact bath in the absence of fluid water, then decoloring only the surface layer of the dyed fabric, subsequently shaving off the surface layer of the decolored fabric and thereby exposing deep-color parts in the interior of the fabric. <P>COPYRIGHT: (C)2004,JPO

Description

【００５６】
表から明らかなように、流動水のない状態でオゾンガスと接触させた実施例１の方が、流動水が存在する状態でオゾンガスと接触させた比較例１に比べて、表面層を削り取っていない部分（淡色部）のトータルＫ／Ｓが小さい値を示していて、同じ量のオゾンガスを投入した場合に、より効率良く脱色できていることがわかる。特にこの点はインディゴ及び反応染料において顕著である。また、特に反応染料を使用した場合には実施例１の方が比較例１に比べてコントラストが大きく、本発明の方法によって高コントラストの模様柄を得たい場合には好適であることがわかる。
【００５７】
【発明の効果】
本発明の模様柄形成方法によれば、斬新でコントラストの高い模様柄を容易に形成できる。しかも、オゾンガスを効率的に利用でき、廃水処理が容易で環境負荷の小さい、模様柄形成方法を提供することができる。[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a method for forming a pattern on a dyed cloth and a dyed cloth on which a pattern is formed by the method. In particular, the present invention relates to a method for forming a pattern in which only a surface layer of a dyed fabric is decolorized with ozone gas, and then a dark color portion inside the cloth is exposed by scraping off the surface layer of the decolored fabric.
[0002]
[Prior art]
When a part that rubs well with another while wearing a textile product becomes lighter in color than the other part due to the friction, a texture appears as if it has been used for a long time. In textile products such as jeans, so-called vintage processing is performed in order to give such a texture. In this processing method, the surface of an easily rubbed portion of the dyed fiber product is shaved to lighten the color of the portion. For example, the surface of a textile product is shaved by various methods such as sandblasting with sand, brushing with a brush, or shaving with a sandpaper.
[0003]
On the other hand, ozone is a gas having a strong oxidizing property, and a method of using this gas to form a decolorized pattern on a dyed product is known. For example, JP-A-4-100987 discloses a method for decolorizing a fiber dyed material by exposing the fiber dyed material to an ozone atmosphere in a humid state. Thus, a bleached pattern having a bleaching contrast can be obtained. According to the gazette, the degree of decolorization is maximized when the moisture content is about 50 to 60%, and the degree of decolorization is reduced even more than that. In addition, the method of decolorizing with ozone in this way reduces the burden of wastewater treatment as compared with the method of decolorizing with a bleach-containing aqueous solution.
[0004]
Japanese Patent Application Laid-Open No. 5-186973 discloses that a denim product dyed with a slen dye (including indigo) or a reactive dye is washed with water in a washing machine while injecting ozone gas, and after the surface of the denim product is decolorized. There is described a method of bleaching and coloring, in which the denim product is dried once, the surface of the denim product is scraped off with sand or the like, and the unbleached portion remaining in the middle layer is exposed to form a color.
[0005]
[Problems to be solved by the invention]
With the diversification of consumer needs in recent years, the formation of novel patterns has come to be desired. The pattern obtained by the method described in Japanese Patent Application Laid-Open No. 5-186973 is novel in that the portion whose surface is shaved develops a dark color, and the pattern obtained by so-called vintage processing is inverted from the pattern obtained by so-called vintage processing. It is interesting.
[0006]
According to the method described in JP-A-5-189693, an ozone gas is injected into a stirring tank while the dyed fabric is stirred with water. However, according to the method described in this publication, the decolorization rate by ozone is slow, and the production efficiency is not high. Since the production cost of ozone gas used for decolorization is not always inexpensive, if the decolorization speed is low and the efficiency of use of ozone gas is low, the cost of the entire treatment process will increase. In addition, it is difficult to form a dark portion having a high contrast after sufficiently lightening the surface, and there are restrictions on the patterns that can be formed.
[0007]
Furthermore, in the method described in Japanese Patent Application Laid-Open No. Hei 5-18673, wastewater in which a considerable amount of ozone gas is dissolved is generated after the decolorizing operation. Ozone gas tends to volatilize from wastewater containing ozone gas, and handling such wastewater in an open system may deteriorate the working environment and the surrounding environment. On the other hand, if the wastewater treatment is performed in a completely closed system, the treatment cost increases.
[0008]
The present invention has been made in order to solve the above-mentioned problems, and it is possible to efficiently use ozone gas, form a high-contrast pattern, and easily treat wastewater with a small environmental load. It is intended to provide a method of forming.
[0009]
[Means for Solving the Problems]
The above-mentioned problem is a method for forming a pattern on a dyed fabric. After the dyed fabric is made to contain moisture, the dyed fabric is brought into contact with ozone gas in a contact tank free of flowing water to decolorize only the surface layer of the dyed fabric. After that, the problem is solved by providing a pattern forming method characterized in that the dark layer inside the fabric is exposed by scraping off the surface layer of the bleached fabric. By contacting the dyed fabric containing water with ozone gas in the absence of flowing water, only the fabric surface can be efficiently decolorized, and wastewater treatment is also easy.
[0010]
At this time, it is preferable that the dyed fabric is a woven fabric in which both the warp and the weft are dyed up to the core and the basis weight is 170 g / m ² or more, since only the surface layer is easily decolorized. Further, it is preferable that the dyed fabric is dyed with a reactive dye or indigo because a pattern with high contrast can be easily formed efficiently.
[0011]
Also, at this time, if the water is contained in 50 to 90 parts by weight with respect to 100 parts by weight of the dyed fabric and then brought into contact with the ozone gas, the decolorization speed with the ozone gas is high, and only the surface layer can be decolorized. preferable. It is preferable that the maximum concentration of the ozone gas in the contact tank when it is brought into contact with the ozone gas is 1 to 200 g / m ³ from the viewpoint of the balance between the decolorization rate and the use efficiency of the ozone gas. Is preferably 2 to 100 minutes from the viewpoint of production efficiency. Further, the concentration of the ozone gas in the gas introduced into the contact tank is 10 to 500 g / m ³ , and the flow rate of the gas introduced per minute is 0.1 to 10 volume of the internal volume of the contact tank. % Is preferable in terms of device design.
[0012]
It is a preferred embodiment of the present invention that the total K / S of the portion of the decolorized fabric where the surface layer is not scraped is 40 or less. In a preferred embodiment of the present invention, it is also preferred that the total K / S of the decolorized cloth at the portion where the surface layer is removed is 10% or more of the total K / S at the portion where the surface layer is not removed. is there.
[0013]
The above object is also achieved by providing a dyed fabric having a pattern formed by the above pattern forming method.
[0014]
BEST MODE FOR CARRYING OUT THE INVENTION
The present invention is a method for forming a pattern on a dyed fabric, wherein after the dyed fabric is made to contain water, the dyed fabric is brought into contact with ozone gas in a contact tank free of flowing water to decolorize only the surface layer of the dyed fabric. After that, the surface layer of the decolorized cloth is scraped off to expose a dark-colored portion inside the cloth.
[0015]
The material of the dyed fabric used in the present invention is not particularly limited, and various natural fibers, synthetic fibers, and recycled fibers can be used. Above all, cellulosic fiber materials are important because they are widely used for clothing such as jeans that want to form a natural pattern by shading. Examples of the cellulosic fiber material include cotton, hemp, rayon, polynosic, "Tencel", "Lyocell", acetate, triacetate and the like, and cotton is the most important.
[0016]
The dye used for dyeing the dyed fabric used here is not particularly limited. Ozone is a powerful oxidizing agent and can decolorize various dyes. Direct dyes, acid dyes, basic dyes, vat dyes, sulfur dyes, reactive dyes and the like can be used. As described above, in the present invention, since a dyed fabric made of cellulosic fibers is important, direct dyes, vat dyes, reactive dyes, and sulfur dyes that are suitable for dyeing cellulosic fibers are preferably used. You. Among these, indigo, which is a vat dye for which there is a great market need for forming a pattern on denim fabric, is particularly preferably used. In addition, a reactive dye is particularly preferably used because it is easy to efficiently form a high-contrast pattern.
[0017]
The form of the dyed fabric is not particularly limited, and various woven or knitted fabrics can be used. However, a woven fabric having a basis weight of 170 g / m ² or more is preferable because only the surface layer is easily decolorized. A woven fabric having a basis weight of a certain level or more is preferable because a decoloring contrast between the surface layer of the fabric and the inside of the fabric can be easily formed. It is more preferably at least 300 g / m ² , even more preferably at least 400 g / m ² . Therefore, a denim fabric that is a thick twill fabric made of cellulosic fibers is particularly preferably used. It is preferable that the dyed fabric is a woven fabric in which both the warp and the weft are dyed up to the core in order to obtain a high-contrast pattern.
[0018]
The dyed cloth used in the pattern forming method of the present invention may be in the form of an unsewn cloth or a sewn product. When it is in the form of a cloth, the surface layer may be cut in the form of a cloth after decolorization and then sewn.However, it is better to sew and then cut off the surface layer in a desired place of the clothing. It is preferable because a pattern can be easily formed. A more preferred method is to remove the color of the sewn garment as it is and then to scrape off the surface layer. According to this method, it is easy to deal with small lots and the production efficiency is good.
[0019]
In the case of using the sewn clothing, the type of clothing is not particularly limited. Patterns can be formed on various types of clothing such as pants, shirts, skirts, and jackets. Above all, denim pants and denim jackets are the most important since there is a great need in the market for forming natural patterns by shading.
[0020]
The method of adding moisture to the dyed fabric is not particularly limited, but a method of stirring with water in a rotating drum and then performing a centrifugal dehydration treatment is exemplified. In the present invention, since it is necessary to perform treatment in the subsequent operation in the absence of flowing water, it is necessary to adjust the water content to such an extent that there is no flowing water by centrifugal dehydration or the like. After the centrifugal dehydration treatment, the dyed fabric is often pressed against the inner wall of the drum and unnaturally bends. Therefore, it is preferable that the drum is once rotated at a low speed to loosen it. By doing so, the ozone gas can be uniformly brought into contact with the entire dyed fabric. The rotation time of the drum in this operation is usually about 1 to 60 minutes.
[0021]
The preferred moisture content of the dyed fabric when it is brought into contact with ozone gas is 50 to 90 parts by weight of water based on 100 parts by weight of the dyed fabric. Here, the weight of the dyed fabric as the raw material is an amount containing the moisture already contained under a normal environment.
[0022]
If the moisture content of the dyed fabric is too high or too low, the decolorization speed of the fabric surface layer tends to decrease. When the water content is 50 to 60 parts by weight with respect to 100 parts by weight of the dyed fabric, the decolorization speed of the surface layer is maximum, and when the water content is 50 parts by weight or less, the decolorization speed is reduced. On the other hand, when the water content exceeds 90 parts by weight with respect to 100 parts by weight of the dyed cloth, particularly in a situation where flowing water is present in the contact tank, the surface layer is decolorized to some extent, but the decolorization speed is reduced. It is preferable that the surface layer of the fabric can be decolorized as efficiently as possible from the viewpoint of ozone gas utilization efficiency.
[0023]
On the other hand, when the water content is less than 50 parts by weight based on 100 parts by weight of the dyed fabric, the inside of the fabric is decolorized almost in the same manner as the surface layer, and the pattern and pattern intended for the present invention can be formed. In many cases, it is difficult to form a pattern with high contrast. On the other hand, when the water content is 50 parts by weight or more with respect to 100 parts by weight of the dyed fabric, the internal bleaching speed is reduced as compared with the surface layer, and only the surface is selectively bleached. Thus, the pattern of the present invention can be formed. The contrast of the density between the surface of the cloth and the inside of the cloth becomes maximum when the water content is 65 to 70 parts by weight with respect to 100 parts by weight of the dyed cloth.
[0024]
When contacted with ozone gas in a limited moisture content range of 50 to 90 parts by weight with respect to 100 parts by weight of the dyed fabric, the surface layer of the dyed fabric has a high decolorizing speed, and the interior is It is easy to show a characteristic bleaching behavior that is difficult to bleach. In addition, in the case of such a water content, there is no fluidized water in the contact tank, and waste ozone gas can be treated in a gas phase, which is preferable from the viewpoint of wastewater treatment.
[0025]
The content of water with respect to 100 parts by weight of the weight of the dyed fabric is to be appropriately adjusted according to the specifications of the dyed fabric to be used and the intended pattern, but the lower limit is more preferably 60 parts by weight or more, More preferably, it is at least 65 parts by weight. On the other hand, the upper limit of the water content is more preferably 80 parts by weight or less, and still more preferably 70 parts by weight or less.
[0026]
After adding moisture to the dyed fabric as described above, the dyed fabric is brought into contact with ozone gas in a contact tank free of flowing water to decolor only the surface layer of the dyed fabric. At this time, it is important to make contact without flowing water. As described above, in the state where the flowing water exists, the decolorization speed of the surface layer of the dyed fabric is slow, and the ozone gas cannot be used efficiently. In addition, when the flowing water in which the ozone gas is dissolved is discharged after the decoloring operation, the working environment and the surrounding environment may be deteriorated due to the volatilization of the ozone gas.
[0027]
The container to be brought into contact with the ozone gas is not particularly limited as long as it is capable of sealing the ozone gas. Usually, however, the ozone gas is continuously introduced and the gas inside is continuously discharged at the same time. The container preferably has a means capable of stirring, and preferably the dyeing garment can be stirred in a rotating drum. It is preferable to perform both the operation of adjusting the water content and the operation of stirring while being brought into contact with the ozone gas in a single tank because the workability is good. In such a case, a washer with a rotating drum that can perform washing and dewatering operations is suitably used.
[0028]
The generator of the ozone gas is not particularly limited, and any of an electrolysis type, a discharge type, and an ultraviolet type can be used. Among them, in the case of the ultraviolet type, the ozone gas concentration may be insufficient, and in order to obtain a gas containing a high concentration of ozone gas, it is preferable to use an electrolytic or discharge type generator. In order to obtain a large amount of ozone gas, a discharge type, particularly a silent discharge type ozone generator is preferably used. The amount of ozone gas generated is adjusted depending on the capacity of the contact tank, the weight of the dyed fabric to be treated, and the like.
[0029]
Staining fabric when contacted with the ozone gas, the highest concentration of ozone gas in the contact vessel is preferably 1-200 g / m ^3. If the concentration is too low, the speed of decolorizing the surface layer of the dyed fabric will be too slow to be efficient, and if the concentration is too high, the inside of the dyed fabric will be easily decolorized. The maximum concentration of the ozone gas is preferably 2 g / m ³ or more, more preferably 5 g / m ³ or more. Further, it is preferably 100 g / m ³ or less, more preferably 50 g / m ³ or less. The maximum concentration of the ozone gas referred to here is obtained by measuring the concentration of the ozone gas in the gas discharged from the contact tank. The concentration of ozone gas in the contact tank gradually increases as the gas containing ozone gas is introduced, but the maximum concentration of the ozone gas is the concentration at which the ozone gas reaches its maximum during the contact operation. Normally, the concentration at the time of ending the contact operation often becomes the maximum, but in some cases, when the concentration is increased to a certain concentration on the way, the ozone gas supply capacity may be reduced and adjusted.
[0030]
A gas containing ozone gas is introduced into the contact tank so as to achieve such an ozone gas concentration. The ozone gas concentration of the introduced gas is set in consideration of the flow rate of the introduced gas, the internal volume of the contact tank, and the amount consumed in the tank. Usually, the concentration is set to be much higher than the concentration in the tank, for example, about 10 to 500 g / m ³ . The ozone gas concentration of the introduced gas is preferably at least 50 g / m ³ , and more preferably at least 100 g / m ³ . It is preferably 300 g / m ³ or less. If the flow rate of the introduced gas is too large, the amount of unreacted ozone gas discharged increases and the utilization efficiency decreases. If the flow rate of the introduced gas is too small, the decoloring operation takes too much time. Usually, it is preferable to introduce a gas of about 0.1 to 10% by volume of the inner volume of the contact tank per minute. More preferably, it is 0.2% by volume or more and 5% by volume or less.
[0031]
The time for bringing the ozone gas into contact with the dyed fabric is usually 2 to 100 minutes. If the contact time is too short, the decolorization of the surface layer of the dyed fabric may be insufficient, more preferably 5 minutes or more, and even more preferably 10 minutes or more. On the other hand, if the contact time is too long, the decolorization inside the dyed fabric may also proceed, and it is more preferably 60 minutes or less, and still more preferably 40 minutes or less. During this time, it is preferable that stirring be continued, since unevenness in decolorization can be reduced when viewed from the entire dyed fabric.
[0032]
After the contact operation is completed, the ozone gas in the contact tank is discharged. The method of discharging the ozone gas is not particularly limited, and examples thereof include a method of blowing compressed air to replace the gas in the contact tank. The ozone gas discharged after the contact operation and the ozone gas derived from the contact tank during the contact operation are decomposed and then released to the atmosphere. The method for decomposing ozone gas is not particularly limited, and a known method can be employed. For example, a pyrolysis method, an activated carbon method, a chemical solution treatment method, a catalyst method and the like can be exemplified. The decomposition operation by the catalytic method is industrially suitable because of the decomposition cost and the ease of maintenance.
[0033]
In a decoloring method using a liquid bleaching agent, as in a method widely used in the related art, it is necessary to treat a waste liquid in which a large amount of the bleaching agent remains. Currently, bleaching agents widely used in textile processing applications are oxidizing agents such as sodium hypochlorite. When the aqueous solution containing such an oxidizing agent is treated as wastewater, since the degrading bacteria in the sludge may be weakened if the solution is directly introduced into the activated sludge tank, the sludge is treated with a reducing agent in advance and then transferred to the activated sludge tank. The method of inputting is adopted. However, this requires the use of more chemical substances for waste liquid treatment, which imposes a heavy burden on the environment and increases the labor and cost of the treatment. On the other hand, as described above, in the present invention in which ozone gas is used as a decolorizing agent, ozone gas can be decomposed by simple treatment in the gas phase, which is useful from the viewpoint of waste liquid treatment and load on the surrounding environment. Is a great way.
[0034]
After the ozone gas is discharged, the dyed fabric is washed to remove a small amount of remaining ozone by washing. At the time of washing, washing may be performed with cold water or warm water, or a surfactant may be contained in the washing water. After washing with the washing water containing the surfactant, rinsing with water is further performed. After such a washing operation, dehydration treatment is performed, but centrifugal dehydration is preferred. In this way, only the surface layer of the dyed fabric is decolorized, and a dyed fabric having a dark portion inside the fabric is obtained.
[0035]
The dehydrated dyed cloth usually contains 40 to 90 parts by weight of water with respect to 100 parts by weight of the dyed cloth. In particular, in the case of centrifugal dehydration, unnatural wrinkles are left by being pressed against the drum, so it is preferable to perform an operation of elongating this and then scraping the surface layer of the fabric. The method of extending the wrinkles is not particularly limited, and the wrinkles may be extended while containing water, or may be dried and then extended. In the pattern forming method of the present invention, since the surface layer of the fabric is scraped off after the wrinkles are stretched, it is necessary to wash again after the scraping. Therefore, since the operation of once drying in the middle is useless from the viewpoint of work efficiency or energy use efficiency, it is preferable to stretch wrinkles while containing moisture and to scrape off the surface layer of the fabric while still containing moisture. . As a method of extending wrinkles while containing water, a method of blowing wrinkles by blowing high-temperature steam or high-temperature air for a short time is suitably adopted. For example, in the case of clothing such as pants and a jacket, it is preferable to blow a high-temperature steam or high-temperature air into the clothing using a finishing machine to finish wrinkles. The moisture content does not fluctuate greatly before and after the wrinkle removing step, and the state usually contains 30 to 60 parts by weight of moisture even after the step.
[0036]
For the dyed fabric whose surface layer has been bleached and preferably wrinkled, the surface layer is scraped off to expose a dark color portion inside the fabric. The method of shaving off the surface layer is not particularly limited as long as it is a method capable of exposing an inner dark portion to form a pattern. Various methods such as sand blasting by spraying particles such as sand, brushing by rubbing with a brush, or shaving by rubbing with sandpaper or the like can be adopted, and are appropriately selected according to the intended pattern.
[0037]
After the surface layer has been scraped off, it is washed to remove deposits such as shavings and sand. Subsequent drying gives a dyed fabric on which the desired pattern is formed. When the total K / S of the portion of the obtained fabric where the surface layer is not scraped is decolorized to a level of 40 or less, more preferably 30 or less, there is a great benefit of adopting the method of the present invention having a high decoloration rate. . Here, the total K / S is a value obtained by summing 16 K / S values at 16 wavelengths measured every 20 nm in a measurement range of 400 nm to 700 nm. The K / S function (Kubelka-Munk function) is represented by the following equation. The measurement conditions are as described in the examples.
K / S = (1−ρ) ² / 2ρ
Here, ρ is the spectral reflectance (0 <ρ ≦ 1).
[0038]
In addition, the total K / S of the portion where the surface layer is not removed is larger than the total K / S of the portion where the surface layer is not removed by 10% or more, preferably 20% or more, and more preferably 30% or more. It is preferable because a pattern having a clear contrast can be formed. In other words, when forming a pattern in which the portion of the surface layer that has not been removed is sufficiently lightened, and the portion of which the surface layer has been removed is sufficiently dark, a high-contrast pattern is formed with good productivity. There is great significance in adopting the method of the present invention that can be used.
[0039]
The pattern thus obtained is a novel pattern that could not be easily obtained conventionally. For example, if a portion that is easily rubbed, such as the upper surface of the knee, of the pants is darkened, it is possible to form a pattern pattern that is the inverse of the so-called vintage processing. With the diversification of consumer needs in recent years, fiber products of various designs have been required, and the present method provides one method for meeting such needs.
[0040]
【Example】
Hereinafter, the present invention will be described in more detail with reference to Examples.
[0041]
Example 1
Six cotton pants (total weight: 4 kg) described below were prepared and used as dyed clothing for forming a pattern.
[0042]
・ Dyeing clothing 1 (two):
Indigo denim pants that have been subjected to desizing treatment with 60 ° C warm water containing amylolytic enzymes and then dried. The basis weight of the fabric is 14 oz / square yard (475 g / m ² ), the warp is dyed such that the undyed portion remains in the core, and the weft is an undyed white yarn.
[0043]
・ Dyeing clothing 2 (two):
Denim pants that have been dyed with 2% owf direct dye ("Kayaras Supra Blue BWL134" manufactured by Nippon Kayaku Co., Ltd.) after the sewing process; The fabric weight is 12 ounces / square yard (407 g / m ² ), and both the warp and the weft are dyed up to the core.
[0044]
・ Dyeing clothing 3 (1):
Denim pants that have been dyed with a mixture of the following three types of dyes (red color; reactive dye 1) manufactured by Daistar Japan Co., Ltd. after sewing and then dried once. The fabric weight is 12 ounces / square yard (407 g / m ² ), and both the warp and the weft are dyed up to the core.
"Remazol Reanova Yellow CA" 1.872% owf
"Remazol Reanova Red CA" 1.758% owf
"Remazol Reanova Blue CA" 0.835% owf
[0045]
・ Dyeing clothing 4 (1):
Denim pants that have been dyed with a mixture of the following three dyes (green; reactive dye 2) manufactured by Daistar Japan Co., Ltd. after sewing and then dried once. The fabric weight is 12 ounces / square yard (407 g / m ² ), and both the warp and the weft are dyed up to the core.
"Remazol Reanova Yellow CA" 2.298% owf
"Remazol Reanova Red CA" 0.502% owf
"Remazol Reanova Blue CA" 1.203% owf
[0046]
The decolorizing apparatus used in this embodiment is an industrial washer in which an ozone generator and a waste ozonolysis device are connected via a pipe. The industrial washer used was "LAVNET IWE-22EB" manufactured by Inamoto Mfg. Co., Ltd., which is a fully-automatic horizontal rotation type. The inner volume of the treatment tank is 580 liters, and operations such as stirring, washing, and dehydration can be performed by a rotating drum inside the treatment tank. The ozone generator connected to this is “Ozone Master OM-72” manufactured by Sasakura. Ozone is generated by an electrolysis method, and the ozone gas generation capacity is 72 g / hour at the time of operation at the maximum output, and the ozone concentration in the gas introduced into the tank at that time is 210 g / m ^3. It is. The flow rate of the introduced gas is about 6 liters / minute. The exhaust ozonolysis treatment device connected to the washer is of a type in which a derived gas is bubbled in an aqueous potassium iodide solution.
[0047]
The six pants were put into the tank of the decolorizer, 80 liters of water were injected, the drum was rotated, washed with water at 30 ° C. for 5 minutes, and then centrifugally dehydrated. After centrifugal dehydration, the whole pants were loosened by rotating at low speed for 15 minutes. The pants thus obtained contained a total of 2.8 kg (70 parts by weight with respect to 100 parts by weight of pants) of six pants. At this time, no flowing water was present in the tank, and moisture was retained inside and on the surface of the fabric of the pants.
[0048]
Subsequently, the rotation of the drum was continued while introducing a gas containing ozone gas at a concentration of 210 g / m ^{3 into} the tank at a flow rate of about 6 l / min. While this operation was continued for 20 minutes, the ozone gas concentration in the tank gradually increased, and after 20 minutes, rose to 18 g / m ³ . This concentration is obtained by measuring the concentration of ozone gas in the gas discharged from the contact layer. After 20 minutes, supply of ozone gas was stopped, and residual ozone gas was discharged for 20 minutes while introducing compressed air into the tank. The ozone gas discharged in the step of contacting with ozone gas and the step of discharging residual ozone was removed by bubbling in an aqueous solution of potassium iodide and then released into the atmosphere.
[0049]
After the operation of discharging the ozone gas, 80 liters of water was poured into the tank and stirred for 5 minutes to wash and remove ozone slightly remaining in the dyed fabric after the decolorizing treatment. Subsequently, 80 liters of warm water and 120 g of a surfactant were added, and a soaping and washing operation was performed at 70 ° C. for 10 minutes. Subsequently, after a washing step with hot water at 60 ° C. and a washing step with water, the spin-drying was performed, and then high-temperature steam was blown in with a finisher to expand wrinkles formed during the spin-drying. The wrinkled pants were subjected to sandblasting while keeping the water content, and the surface of the portion corresponding to the knee was selectively scraped off. Thereafter, the pants were put into a washer and washed with water to remove attached shavings and sand, dehydrated, and dried.
[0050]
In the pants obtained in this way, the part scraped off by sandblast became darker than the other parts. The degree of coloring of the surface of the obtained pants was measured for a portion where the surface layer was scraped off and for a portion where the surface layer was not scraped off. At the time of measurement, the degree of coloring was evaluated by total K / S. The total K / S is a value obtained by summing 16 K / S values at 16 wavelengths measured at intervals of 20 nm in a measurement range of 400 nm to 700 nm. ). The measurement results are shown in Table 1.
[0051]
In addition, the same test as described above was performed by changing only the moisture content when contacting with the ozone gas, and the effect of the moisture content on the pattern was examined. As a result, with a water content of 65 parts by weight with respect to 100 parts by weight of the pants, a pattern substantially similar to the above example (70 parts by weight) could be obtained. At 75 parts by weight, the degree of coloring in the portion where the surface layer was not removed was slightly increased, and the contrast was slightly lowered. At 80 parts by weight, the degree of coloring of the portion where the surface layer was not scraped was increased, and the contrast was considerably reduced. At 90 parts by weight or more, the degree of coloring of the portion where the surface layer was not scraped was further increased, and the contrast was further reduced. On the other hand, at 60 parts by weight, although the surface layer could be lightened in the same manner as in the above-mentioned example (70 parts by weight), the degree of coloring at the portion where the surface layer had been cut off was lowered and the contrast was lowered. At 55 parts by weight or less, the difference between the degree of coloring of the part where the surface layer was not removed and the degree of coloring of the part where the surface layer was removed was small, and the contrast was greatly reduced.
[0052]
Comparative Example 1
The same six pants used in Example 1 were put into the same decoloring apparatus tank as in Example 1, 80 liters of water were injected, and the drum was rotated to wash at 30 ° C. for 5 minutes. Once drained. After draining, 80 liters of water at 30 ° C. was injected again.
[0053]
Subsequently, the rotation of the drum was continued while a gas containing ozone gas at a concentration of 210 g / m ³ was bubbled into the water in the tank at a flow rate of about 6 l / min. While this operation was continued for 20 minutes, the ozone gas concentration in the tank gradually increased, and after 20 minutes, increased to 25 g / m ³ . This concentration is obtained by measuring the concentration of ozone gas in the gas discharged from the contact layer. After 20 minutes, the supply of the ozone gas was stopped, and the ozone gas remaining in the air in the tank and the ozone gas dissolved in the water were discharged while blowing compressed air into the water in the tank for 20 minutes. The ozone gas discharged in the step of contacting with ozone gas and the step of discharging residual ozone was removed by bubbling in an aqueous solution of potassium iodide and then released into the atmosphere. After discharging the residual ozone gas, the water in the tank was discharged. However, ozone remained in the drainage, and an ozone odor was generated.
[0054]
After the above decolorization operation, a pattern was formed on the pants in the same manner as in Example 1, and the total K / S was measured as in Example 1. The measurement results are shown in Table 1.
[0055]
[Table 1]

[0056]
As is clear from the table, the surface layer of Example 1 which was brought into contact with the ozone gas in the state where there was no flowing water was not scraped as compared with Comparative Example 1 which was brought into contact with the ozone gas in the state where there was flowing water. The total K / S of the portion (light colored portion) shows a small value, and it can be seen that when the same amount of ozone gas is supplied, decolorization can be performed more efficiently. This point is particularly remarkable in indigo and reactive dyes. Further, in particular, when a reactive dye is used, Example 1 has a higher contrast than Comparative Example 1, and it can be seen that the method is suitable for obtaining a high-contrast pattern by the method of the present invention.
[0057]
【The invention's effect】
According to the pattern design method of the present invention, a novel pattern with high contrast can be easily formed. In addition, it is possible to provide a pattern forming method in which ozone gas can be efficiently used, wastewater treatment is easy, and the environmental load is small.

Claims (10)

A method for forming a pattern on a dyed fabric, wherein after the dyed fabric is made to contain moisture, it is brought into contact with ozone gas in a contact tank free of flowing water to decolorize only the surface layer of the dyed fabric, and then decolorized. A pattern forming method, characterized by exposing a dark-colored portion inside the fabric by scraping off the surface layer of the finished fabric. Dyeing the fabric, the warp yarns, a textile dyed to the core in the weft both design pattern forming method according to claim 1, wherein the basis weight is 170 g / m ² or more. The pattern forming method according to claim 1 or 2, wherein the dyed fabric is dyed with a reactive dye or indigo. The pattern forming method according to any one of claims 1 to 3, wherein 50 to 90 parts by weight of water is contained with respect to 100 parts by weight of the dyed fabric, and then contacted with ozone gas. When contacting the ozone gas, the maximum concentration of 1-200 g / m ³ a pattern Pattern forming method according any one of claims 1 to 4 of the ozone gas in the contact vessel. The pattern forming method according to any one of claims 1 to 5, wherein the contact time of the ozone gas in the contact tank is 2 to 100 minutes. The concentration of ozone gas in the gas introduced into the contact tank is 10 to 500 g / m ³ , and the flow rate of the gas introduced per minute is 0.1 to 10% by volume of the internal volume of the contact tank. The pattern forming method according to any one of claims 1 to 6. The pattern / pattern forming method according to any one of claims 1 to 7, wherein the total K / S of a portion of the decolorized cloth where the surface layer is not removed is 40 or less. The pattern according to any one of claims 1 to 8, wherein the total K / S of the portion of the decolorized cloth from which the surface layer has been removed is at least 10% greater than the total K / S of the portion where the surface layer has not been removed. Forming method. A dyed cloth having a pattern formed by the pattern forming method according to claim 1.