KR102345167B1 - Method for dyeing towel - Google Patents

Abstract

The present invention relates to a method for dyeing a towel and to an apparatus for performing the method. The method may include the steps of: performing a pre-dyeing treatment; performing dyeing; and performing a post-dyeing treatment. The pre-dyeing treatment, dyeing, and post-dyeing treatment are performed according to a type of cotton yarn. The type of cotton yarn is lead-free and general cotton yarn.

Description

Towel dyeing method {Method for dyeing towel}

The present invention relates to a method for dyeing towels. More particularly, it relates to a towel dyeing method and apparatus for an eco-friendly and efficient dyeing process than conventional ones.

There are about 150 domestic towel makers, and more than 50% of them are concentrated in Daejeon and Chungnam alone. In addition, through frequent exchanges with Japan, which is known as a world-class, domestic towel manufacturing technology is also close to the world level, but it has an export-driven industrial structure that relies on exports for about 43% of total production due to a lack of domestic market. On the other hand, in Japan's towel market, 140 companies are in business in Imabari towel producing area (Shikoku area), which is a dyeing process business complex, and about 100 companies are in business in Izumisano towel producing area (Osaka area), which is a post dyeing process company complex (Osaka area). As an industry, regional cooperatives have been formed to develop government-funded technologies and conduct quality tests. Japan has a strong economic circulation structure in which 84% of production is consumed in the domestic market, and most consumers purchase products directly from the market, producing various and practical products for each use, and developing various high-value-added fashion material applications. Thus, a small-volume production system is being implemented.

Among these towel production processes, the dyeing process can cause environmental pollution because various chemicals are used. In addition, the dyeing process requires a long time. Therefore, a dyeing process with high eco-friendliness and a dyeing process for improving the dyeing quality while shortening the dyeing time are required.

Korean Patent Registration No. 10-1061436

An object of the present invention is to solve all of the above problems.

In addition, an object of the present invention is to make the dyeing process more environmentally friendly through changes in the dyeing process chemicals used in the past.

In addition, the present invention enables the production of high-quality towels by shortening the time of the previously performed dyeing process through a drug additionally used in the dyeing process, but bringing a higher dyeing effect, while lowering production efficiency and production cost aim to

As a means for achieving the above object,

The present invention provides a method for dyeing a non-twisted yarn towel, comprising: performing a dyeing pretreatment; performing dyeing using a towel dyeing apparatus; and performing post-dyeing treatment, wherein the dyeing pretreatment includes a preliminary refining step, a bleaching step, wherein the preliminary refining step is performed without a refining agent, and the bleaching step is caustic soda, hydrogen peroxide, a refining agent and is carried out using a lubricating cushioning agent in the bath, the post-dyeing treatment includes a neutralizing step, a soaping step, a cold water washing step, a softening step, the soaping step is performed using a low-temperature soaping agent, and the cold water washing step is a cell It is performed based on a solution containing rollase, and the softening step is performed using a non-ion type silicone softener, the pre-refining step is performed at 80 degrees Celsius for 10 minutes, and the bleaching step is performed at 95 degrees Celsius It is carried out for 30 minutes, and the towel dyeing apparatus includes a dyeing machine (A), a nanobubble providing means (B) installed on one side of the dyeing machine to provide nanobubbles, and a moisture and contaminated air installed on one side of the dyeing machine and installed on the outside of the dyeing machine. It is characterized in that it comprises a moisture and polluted air removing means 100a for removing the dye, and a polluted air measuring device 3000 installed on one side of the dyeing machine to inform the outside of the contamination state of the air outside the dyeing machine.

In addition, the nano-bubble providing means, the frame body (100b) made of a polygonal frame shape; a filtering device 200 installed on the outer side of the frame body and filtering and removing foreign substances; a water tank 300 communicated adjacent to the filtering device and installed on the frame body to draw water to the outside; a pump 400 communicated adjacent to one side of the water tank, installed on the frame body, applied pressure to water flowing out from the water tank, and driven by receiving electric power from the outside; It communicates adjacent to one side of the pump and is installed on the frame body, and it is characterized in that it comprises a nanobubble generator 500 that generates and then discharges nanobubbles using water flowing out under the pressure of the pump.

The moisture separation and polluted air removal means 100a includes a polluted air collection region 10, a moisture collection region 20, and a partition wall 30 installed between the polluted air collection region and the moisture collection region, , The polluted air collection area 10 accommodates a box 11 in which the polluted air is temporarily stored, and a plurality of fine holes 12 for discharging the polluted air are formed in the lower portion of the polluted air storage box 11. a box (1) for water separation and polluted air treatment; Suction pressure providing hose located in the moisture collection area and providing suction pressure to the moisture collection area to extract moisture from the contaminated air supplied through the contaminated air collection area and to reach the moisture collection area after passing through the bulkhead (2) and; a suction pressure providing device (3) installed at the end of the suction pressure providing hose and providing suction pressure through the suction pressure providing hose; a suction pressure temporary blocking means (20a) located in the moisture collection area and for preventing moisture from rising by blocking suction pressure when moisture is above a certain level; It is characterized in that it is installed in the moisture collection area and consists of a moisture blocking means 24 that induces moisture to fall without being sucked into the suction pressure providing means through the suction pressure providing hose.

In addition, the suction pressure temporary blocking means (20a) is installed in the moisture collection area (20), the rising pressure providing unit 21 designed to float when the moisture fills up, and the air collecting unit installed above the rising pressure providing unit. The air passage type body part ( 22) and, an air passage type that is installed at the end of the air passage type body part, and the passage for air passage (22a) is extended and installed, and when the air passage type body part rises due to the rise of the rising pressure providing part, it rises upward to induce blocking of the suction pressure. It is characterized in that it comprises a piston (23).

In addition, the upper end of the moving bogie is configured to include a polluted air measuring device 3000 for measuring the surrounding air condition and warning the operator if it is higher than the standard; The polluted air measuring device 3000 has a rectangular parallelepiped shape with one side open, and is installed on both side surfaces, and includes: a disk-type rewinding member 3100 installed in a plurality of up and down; a support belt 3600 wound in multiple layers on the rotating shaft of the disk-shaped rewinding member; a kit for measuring polluted air attached to the surface of the support belt (3500); a rotary motor 3400 inserted and coupled to the disk-shaped rewinding member to rotate the disk-type rewinding member by rotation of the motor to move the support belt into and out of the disk-type rewinding member; An elevating shaft is inserted into the rotary motor to induce selective coupling to a plurality of disk-type rewinding members while elevating and lowering the rotary motor, thereby drawing a support belt from the required disk-type rewinding member. It is characterized in that it comprises a vertical transfer cylinder 3300 to withdraw.

In addition, the contaminated air measuring kit includes: a tube member 3510 having a flow path formed therein; a first filter 3520 disposed inside the tube member 3510; a second filter 3530 spaced apart from the first filter 3520 and disposed inside the tube member 3510; and a third filter (3550) spaced apart from the second filter (3530) and disposed inside the tube member (3510); a first reactant 3540 reacting with the gas passing through the first filter 3520 is filled between the first filter 3520 and the second filter 3530; A second reactant 3560 reacting with the gas passing through the second filter 3530 is filled between the second filter 3530 and the third filter 3550 .

According to the present invention, the dyeing process can be performed more environmentally friendly by changing the dyeing process chemicals used in the past.

In addition, according to the present invention, the production efficiency and production cost of towels can be reduced by shortening the time of the dyeing process performed in the past and bringing a higher dyeing effect.

1 is a conceptual diagram showing a dyeing process applied to the present invention.
Figure 2 is a conceptual diagram showing a step before dyeing applied to the present invention.
Figure 3 is a configuration diagram of the dyeing apparatus of the present invention.
Figure 4 is a configuration diagram of the nano-bubble providing means of the present invention.
5 is a configuration diagram of a water separation and pollution measuring device applied to the present invention.
6 is an operation diagram of a water separation and pollution measuring device applied to the present invention.
7 is a block diagram of a polluted air measuring device of the present invention.
Figure 8 is a perspective view of the main part of the polluted air measuring device of the present invention.
9 is a view of operating the first disk-type rewinding member using the vertical transfer cylinder and the rotary motor of the present invention.
10 is a view of operating a second disk-type rewinding member using the vertical transfer cylinder and the rotary motor of the present invention.
11 is a view of operating the third disk-type rewinding member using the vertical transfer cylinder and the rotary motor of the present invention.
12 is a detailed configuration diagram of the air pollution measurement kit of the present invention.

Hereinafter, the principle of operation of the preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings and description. However, the drawings shown below and the description to be given below relate to a preferred implementation method among various methods for effectively explaining the characteristics of the present invention, and the present invention is not limited only to the following drawings and description.

In addition, in the following description of the present invention, if it is determined that a detailed description of a related well-known function or configuration may unnecessarily obscure the gist of the present invention, the detailed description thereof will be omitted. And the terms to be described later are terms defined in consideration of functions in the present invention, which may vary according to intentions or customs of users and operators. Therefore, the definition should be made based on the content throughout the present invention.

In addition, preferred embodiments of the present invention implemented below are already provided in each system functional configuration in order to efficiently describe the technical components constituting the present invention, or system functions normally provided in the technical field to which the present invention belongs The configuration is omitted as much as possible, and the functional configuration to be additionally provided for the present invention will be mainly described.

If a person of ordinary skill in the art to which the present invention pertains, will be able to easily understand the functions of the components already used in the prior art among the functional configurations omitted without being shown below, and the configuration omitted as described above Relationships between elements and components added for purposes of the present invention will also be clearly understood.

In addition, the following examples will be used with appropriate modifications of terms so that those of ordinary skill in the art to which the present invention pertains can clearly understand in order to effectively describe the key technical features of the present invention, thereby It is never limited.

As a result, the technical spirit of the present invention is determined by the claims, and the following examples are one means for efficiently explaining the technical spirit of the present invention to those of ordinary skill in the art to which the present invention belongs. it's just

Moreover, it is to be understood that all detailed description reciting specific embodiments, as well as principles, aspects, and embodiments of the invention, are intended to include structural and functional equivalents of such matters. It should also be understood that such equivalents include not only currently known equivalents, but also equivalents developed in the future, i.e., all devices invented to perform the same function, regardless of structure.

Thus, for example, the block diagrams herein are to be understood as representing conceptual views of illustrative circuitry embodying the principles of the present invention. Similarly, all flowcharts, state transition diagrams, pseudo code, etc. may be tangibly embodied on computer-readable media and be understood to represent various processes performed by a computer or processor, whether or not a computer or processor is explicitly shown. should be

The functions of the various elements shown in the drawings including a processor or functional blocks represented by similar concepts may be provided by the use of dedicated hardware as well as hardware having the ability to execute software in association with appropriate software. When provided by a processor, the functionality may be provided by a single dedicated processor, a single shared processor, or a plurality of separate processors, some of which may be shared.

In addition, the clear use of terms presented as processor, control, or similar concepts should not be construed as exclusively referring to hardware having the ability to execute software, and without limitation, digital signal processor (DSP) hardware, ROM for storing software. It should be understood to implicitly include (ROM), RAM (RAM) and non-volatile memory. Other common hardware may also be included.

In the claims of the present specification, a component expressed as a means for performing the function described in the detailed description includes, for example, a combination of circuit elements that perform the function or software in any form including firmware/microcode, etc. It is intended to include all methods of performing the functions of the device, coupled with suitable circuitry for executing the software to perform the functions. Since the present invention defined by these claims is combined with the functions provided by the various enumerated means and in a manner required by the claims, any means capable of providing the functions are equivalent to those contemplated from the present specification. should be understood as

The above objects, features and advantages will become more apparent through the following detailed description in relation to the accompanying drawings, and accordingly, those of ordinary skill in the art to which the present invention pertains can easily implement the technical idea of the present invention. There will be. In addition, in the description of the present invention, if it is determined that a detailed description of a known technology related to the present invention may unnecessarily obscure the gist of the present invention, the detailed description thereof will be omitted.

Before describing various embodiments of the present invention in detail, it will be understood that the application is not limited to the details of the construction and arrangement of components described in the following detailed description or shown in the drawings. The invention is capable of being embodied and practiced in other embodiments and of being carried out in various ways. Also, device or element orientation (eg, “front”, “back”, “up”, “down”, “top”, “bottom”) The expressions and predicates used herein with respect to terms such as ", "left," "right," "lateral," etc. are used merely to simplify the description of the invention, and the associated apparatus Or it will be appreciated that it does not simply indicate or imply that an element must have a particular orientation.

1 is a conceptual diagram showing a dyeing process applied to the present invention.

Figure 2 is a conceptual diagram showing a step before dyeing applied to the present invention.

Figure 3 is a configuration diagram of the dyeing apparatus of the present invention.

Figure 4 is a configuration diagram of the nano-bubble providing means of the present invention.

5 is a configuration diagram of a water separation and pollution measuring device applied to the present invention.

6 is an operation diagram of a water separation and pollution measuring device applied to the present invention.

7 is a block diagram of a polluted air measuring device of the present invention.

Figure 8 is a perspective view of the main part of the polluted air measuring device of the present invention.

9 is a view of operating the first disk-type rewinding member using the vertical transfer cylinder and the rotary motor of the present invention.

10 is a view of operating a second disk-type rewinding member using the vertical transfer cylinder and the rotary motor of the present invention.

11 is a view of operating the third disk-type rewinding member using the vertical transfer cylinder and the rotary motor of the present invention.

12 is a detailed configuration diagram of the air pollution measurement kit of the present invention;

Referring to FIG. 1 , a dyeing method for increasing production efficiency by reducing the number and amount of chemicals used in the past and reducing process time is disclosed.

The entire dyeing process may be divided into a pre-dyeing step (or dyeing pretreatment) 100 , a dyeing step (or dyeing) 120 , and a post-dyeing step (or dyeing post-processing) 140 . The pre-dyeing step 100 may include a pre-refining step 105 and a bleaching step 110, and the post-dyeing steps are a neutralization step 145, a soaping step 150, a cold water washing step 155, a softening step. (160).

The pre-refining step 105 is a process for removing impurities (fat content, machine oil contamination, etc.) as a process to allow the dye to adhere well to the fiber by removing impurities, contamination, and unnecessary natural pigments attached to the fiber. The pre-scouring step 105 may be applied only to untwisted yarn, and in the case of general cotton yarn, the bleaching step 110 may be performed without the pre-refining step 105 .

The bleaching step 110 is a process of bleaching fibers by removing natural pigments not removed in the preliminary refining process 105 .

The dyeing step 120 is a process of dyeing the towel with a dye.

The neutralization step 145 is a step of neutralizing the dye used for dyeing the towel.

The soaping step 150 is a step of removing after-dyeing located on the towel after dyeing.

Cold water washing step 155 is a step of washing the dyed towel with cold water.

The softening step 160 is a step of softening the towel with a softening agent.

This towel dyeing step may be performed by a towel dyeing apparatus.

The towel dyeing apparatus includes a dyeing machine (A), a nano-bubble providing means (B) installed on one side of the dyeing machine to provide nano bubbles, and a moisture and polluted air removing means installed on one side of the dyeing machine to remove moisture and polluted air (100a) and a polluted air measuring device 3000 installed on one side of the dyeing machine to inform the outside of the polluted state of the air.

The nano-bubble providing means (B), a frame body (100b) made of a polygonal frame shape; a filtering device 200 installed on the outer side of the frame body and filtering and removing foreign substances; a water tank 300 communicated adjacent to the filtering device, installed on the frame body, and for drawing water to the outside; a pump 400 communicated adjacent to one side of the water tank, installed on the frame body, applied pressure to water flowing out from the water tank, and driven by receiving electric power from the outside; It communicates adjacent to one side of the pump and is installed on the frame body, and includes a nano-bubble generator 500 that generates and discharges nano-bubbles using water flowing out under the pressure of the pump.

2 is a conceptual diagram showing a step before dyeing according to an embodiment of the present invention.

In FIG. 2 , a preliminary refining step and a bleaching step are disclosed as a step before dyeing. Both the pre-refining step and the bleaching step may be performed for untwisted yarn, and the bleaching step may be directly performed without the pre-refining step for normal cotton yarn.

In the preliminary refining step for the conventional untwisted yarn, the refining process was performed for 40 minutes after raising the refining solution using the refining agent at 4 degrees per minute from 50 degrees to 98 degrees. Thereafter, a bleaching process was performed with a bleaching solution based on caustic soda, an fruit water stabilizer, and hydrogen peroxide heated from 50 to 98 degrees. In the present invention, 'degree' used to describe the temperature means the Celsius temperature.

In the present invention, a bleaching process that reduces the time of each step may be performed without using conventional chemicals or reducing the dose.

Hereinafter, a preliminary refining step and a bleaching step for untwisted yarn according to an embodiment of the present invention are disclosed.

Referring to FIG. 2 , in the present invention, a preliminary refining process may be performed without using a separate refining agent. That is, in the preliminary refining process, a separate refining agent may not be used unlike the conventional one. The preliminary refining process according to an embodiment of the present invention may be performed for 10 minutes at 80 degrees lower than the existing temperature (98 degrees). That is, even if the preliminary refining process according to an embodiment of the present invention is performed at a lower temperature than before for a short time, the preliminary refining process may be performed in an environmentally friendly manner than the existing preliminary refining process as a process without using a refining agent. In addition, since the preliminary refining process is performed at a low temperature, the time for lowering the temperature for the bleaching process may be reduced compared to the conventional one. According to an embodiment of the present invention, it is possible to perform the preliminary refining process for a short time without a separate refining agent in the preliminary refining process due to the use of an improved refining agent compared to the conventional refining agent used in the subsequent bleaching process.

In addition, the bleaching process for lead-free yarn according to an embodiment of the present invention may be performed without using a water stabilizer, and using caustic soda and hydrogen peroxide having a smaller capacity than before. Specifically, the bleaching process according to an embodiment of the present invention may be performed at 95 degrees for 30 minutes, and may be performed using caustic soda or hydrogen peroxide. The bleaching process can be shortened by 20 minutes from 50 minutes to 30 minutes.

In addition, the present invention may further include a water separation and polluted air removal means (100a) for removing polluted air for the safety of workers at the outer end of the dyeing machine and at the same time separating and processing moisture. The components of the polluted air removal means include a polluted air treatment box 1 for separating moisture, a suction pressure providing hose 2 , a suction pressure providing device 3 , and an air suction hose 4 . Unexplained reference number 5 is the dust 5 contained in the air.

The water separation combined polluted air treatment box (1) is largely composed of two areas centered on the partition wall (30), and consists of a polluted air collection area (10) and a moisture collection area (20), and includes a moisture blocking means; It is made by additionally installing suction pressure temporary blocking means.

The polluted air collection area 10 accommodates a box 11 for temporarily storing polluted air, and a plurality of fine holes 12 for filtering and circulating the polluted air are formed in the polluted air storage box 11 at the bottom. become made

The partition wall 30 serves to separate the polluted air collection area and the moisture collection area, and also serves to prevent the moisture collected in the moisture collection area from retreating again.

In addition, the partition wall may be configured in plurality, and in the present invention, three partition walls are alternately installed and, if necessary, a filter 31 for filtering foreign substances is further installed therein to filter out foreign substances.

The moisture blocking means 24 is installed in the moisture collection area and blocks moisture from being sucked into the suction pressure providing means through the suction pressure providing hose.

The suction pressure temporary blocking means 20a is installed in the moisture collection area 20, the rising pressure providing part 21, the air collecting part 25 installed on the upper part of the rising pressure providing part, and the air collecting part Connected to (25), but installed at the end of the air passage type body portion 22 and the air passage body portion in which the passage for air passage (22a) is formed, the air passage type piston to which the passage for air passage (22a) is extended (23), and when moisture is collected, the rising pressure providing unit 21 rises, and accordingly, the air passage type body 22 and the piston rise, and the piston 23 rises to provide suction pressure It comes into contact with the hose 2 to temporarily close the passage 22a for passing air, and accordingly, it is possible to block direct moisture from entering the suction pressure providing device 3 through the suction pressure providing hose 2 .

That is, the suction pressure temporary blocking means 20a is installed in the moisture collection area 20 and connected to the rising pressure providing part 21 designed to float when the moisture fills up, and the rising pressure providing part to connect the rising pressure. It is installed at the end of the air passage type body portion 22 and the air passage type body portion, in which the suction pressure providing passage (22a) is formed so as to provide suction pressure through the supply unit and at the same time, when the rising pressure supply unit rises due to rising moisture, The suction pressure providing passage (22a) is extended and installed, and when the air passage type body part rises due to the rise of the rising pressure providing unit, it rises upward and is made to include an air passage type piston 23 for inducing blockage of the suction pressure.

In addition, the present invention additionally installs a rising pressure providing part 21, an air passage type body part 22, and a piston 23 because it can be sucked directly into the suction pressure providing hose when the moisture above a certain level is filled. , when the moisture rises above a certain level, the rising pressure providing unit 21 rises, and accordingly, the air passage type body 22 rises, and finally the piston 23 rises and blocks the suction pressure providing hose to further suction No pressure is provided to prevent moisture from being sucked directly into the suction pressure supply hose.

On the other hand, in the present invention, when there is a contamination factor in the working section of the dyeing machine, a device for checking it can be additionally installed, and the polluted air measuring device 3000 is additionally installed to enable real-time check of the contamination state of the air, It was designed to protect the workers by allowing immediate confirmation of the contamination status of the

The polluted air measuring device 3000 for measuring the degree of external air pollution is provided with disk-shaped rewinding members 3100 on both side surfaces, but being inserted into the outer case 3200, and also vertically transporting the disk-shaped rewinding members The rotary motor 3400 was raised and lowered by the cylinder 3300, and then the rotary motor 3400 was self-rotated to rotate the measuring device to measure the polluted air.

That is, a plurality of polluted air measuring kits 3500 are provided, mounted on a supporting belt 3600, and the supporting belt 3600 on which the polluted air measuring kit 3500 is mounted is wound around a disk-type rewinding member, The disc-shaped rewinding member is inserted into the outer case and constituted.

In addition, a plurality of disk-shaped rewinding members 3100 are provided, and the vertical transfer cylinder 3300 is sequentially lowered and the disk-shaped rewinding members 3100 are driven one by one to output a supporting belt, whereby three disk-shaped rewinding members ( 3100) to enable easy measurement of polluted air at regular time intervals.

In addition, in the embodiment of the present invention, three disk-shaped rewinding members 3100 and a kit for measuring contaminated air 3500 of three lines are exemplified, but it is of course that a kit for inspection can be provided and used in more various ways.

In addition, the polluted air measuring kit may be photographed with the camera 3700 and displayed on the display panel 3900 of the display device 3800 to determine whether the color has changed.

The polluted air measuring kit 3500 according to the present invention includes a tube member 3510 having a flow path formed therein, a first filter 3520 disposed inside the tube member 3510, and the first filter 3520 . and a second filter 3530 spaced apart from and disposed inside the tube member 3510, and a third filter 3550 spaced apart from the second filter 3530 and disposed inside the tube member 3510, and , a first reactant 3540 reacting with the gas passing through the first filter 3520 is filled between the first filter 3520 and the second filter 3530 , and the second filter 3530 and A second reactant 3560 reacting with the gas passing through the second filter 3530 is filled between the third filter 3550 .

The tube member 3510 is formed in the shape of a hollow pipe, and the first filter 3520 and the second filter 3530, the third filter 3550 and the first and second reactants 3540 and 3560 therein ) is accepted.

Here, the tube member 3510 is formed to be transparent, so that the degree of discoloration of the second reactant 3560 accommodated therein can be visually confirmed.

The filters 3520, 3530, and 3550 are made of a material such as a breathable polymer compound, polyurethane foam, fluororesin, Teflon resin, glass fiber, polypropylene filter, and silicone plug.

Here, the first filter 3520 serves to filter impurities such as moisture, fine dust, and interference gas in the air introduced into the primary reactant 3540 .

In addition, the second filter 3530 is configured to serve as a support member for accommodating the first reactant 3540 between the first filter 3520 and the third filter 3550. It is configured to serve as a support member for accommodating the second reactant 3560 between the second filter 3530 and the second filter 3530 .

The first reactant is composed of a mercury compound such as mercury, mercury chloride, mercury sulfide, and mercury hydroxide, or a material such as copper sulfate, lead acetate, tin chloride, lead sulfide, lead acetate, iodine, etc. When it comes into contact with methylmercaptan gas An acid or basic gas is generated, and the acid or basic gas thus generated permeates toward the second reactant 3060 .

In addition, the second reactant 3060 is bromophenol blue, bromocresol green, bromocresol purple, methyl red, phenolphthalein, methyl orange, thymol. It is composed of components such as blue (Thymol Blue), phenol red (Phenol Red), Congo Red (Congo Red), and the like, and when the primary reactant meets an acid or basic gas produced by meeting methyl mercaptan gas, the color changes configured to arouse.

Here, the second reactant 3060 is coated on a porous support composed of glucose, silica gel, silica sand, zeolite, diatomaceous earth, a functional polymer sieve, etc., and the second filter 3030 and the third filter 3050 ) are placed between

As the porous support, in addition to the above materials, inorganic or organic compounds that are stable in acid-base reaction may be used.

As described above, by confirming the range 3062 in which the acid or basic gas generated when the first reactant meets the methyl mercaptan gas meets the second reactant 3060 to change color, the concentration of the methyl mercaptan gas included in the odor can be checked easily.

In order to confirm the discoloration range as described above, by displaying a reference line (not shown) on the outside of the tube member 3010 to visually identify whether the discolored range exceeds the reference line, the concentration of the odor is determined by the reference concentration It can be easily determined whether or not

Claims (6)

How to dye a non-twisted yarn towel,
performing dyeing pretreatment;
performing dyeing using a towel dyeing apparatus; and
Including the step of performing post-dyeing treatment,
The dyeing pretreatment includes a preliminary refining step, a bleaching step,
The preliminary refining step is performed without a refining agent,
The bleaching step is carried out using caustic soda, hydrogen peroxide, a refining agent and a lubricating cushioning agent in the bath without a water stabilizer,
The post-dyeing treatment includes a neutralization step, a soaping step, a cold water washing step, a softening step,
The soaping step is performed using a low-temperature soaping agent,
The cold water washing step is performed based on a solution containing cellolase,
The softening step is performed using a non-ion type silicone softener,
The preliminary refining step is performed at 80 degrees Celsius for 10 minutes,
The bleaching step is carried out at 95 degrees Celsius for 30 minutes,

The towel dyeing device,
A dyeing machine (A), a nano-bubble providing means (B) installed on one side of the dyeing machine to provide nano bubbles, and a moisture and polluted air removing means (100a) installed on one side of the dyeing machine to remove moisture and polluted air outside the dyeing machine (100a) ) and a polluted air measuring device 3000 installed on one side of the dyeing machine to inform the outside of the contamination state of the air outside the dyeing machine;

The nano-bubble providing means (B) is,
a frame body 100b formed in the form of a polygonal frame;
a filtering device 200 installed on the outer side of the frame body and filtering and removing foreign substances;
a water tank 300 communicated adjacent to the filtering device, installed on the frame body, and for drawing water to the outside;
a pump 400 communicated adjacent to one side of the water tank, installed on the frame body, applied pressure to water flowing out from the water tank, and driven by receiving electric power from the outside;
It communicates adjacent to one side of the pump and is installed on the frame body, and includes a nano-bubble generator 500 that generates and then discharges nano-bubbles using water flowing out under the pressure of the pump;

The moisture and polluted air removal means (100a) is,
Consists of a polluted air collecting region 10, a moisture collecting region 20, and a partition wall 30 installed between the polluted air collecting region and the moisture collecting region,
The polluted air collection area 10 accommodates a box 11 in which polluted air is temporarily stored, and a plurality of fine holes 12 for discharging polluted air are formed in the lower portion of the polluted air storage box 11 . A box (1) for water separation and polluted air treatment;
Suction pressure providing hose located in the moisture collection area and providing suction pressure to the moisture collection area to extract moisture from the contaminated air supplied through the contaminated air collection area and to reach the moisture collection area after passing through the bulkhead (2) and;
a suction pressure providing device (3) installed at the end of the suction pressure providing hose and providing suction pressure through the suction pressure providing hose;
a suction pressure temporary blocking means (20a) located in the moisture collection area and for preventing moisture from rising by blocking suction pressure when moisture is above a certain level;
and a moisture blocking means (24) installed in the moisture collection area and guiding moisture to fall without being sucked into the suction pressure providing means through the suction pressure providing hose. delete delete The method of claim 1,
The suction pressure temporary blocking means (20a) is,
The rising pressure providing part 21 installed in the moisture collecting area 20 and designed to float when the moisture fills up, the air collecting part 25 installed on the upper part of the rising pressure providing part, and the air collecting part 25 It is installed at the end of the air passage type body part 22 and the air passage type body part where the passage 22a for air passage is formed so as to provide suction pressure by connecting and installing and at the same time, when the rising pressure providing part rises due to rising moisture, Towel, characterized in that it includes an air passage type piston (23) that extends and installs the passage for air passage (22a), and rises upward when the air passage type body part rises due to the rise of the lifting pressure providing unit, thereby inducing blockage of the suction pressure. dyeing method. The method of claim 1,
The polluted air measuring device 3000,
It has a rectangular parallelepiped shape with one side open, and is installed on both side surfaces, and a disk-type rewinding member 3100 that is installed in a plurality of up and down;
a support belt 3600 wound in multiple layers on the rotating shaft of the disk-shaped rewinding member;
a kit for measuring polluted air attached to the surface of the support belt (3500);
a rotary motor 3400 inserted and coupled to the disk-shaped rewinding member to rotate the disk-type rewinding member by rotation of the motor to move the support belt into and out of the disk-type rewinding member;
An elevating shaft is inserted into the rotary motor to induce selective coupling to a plurality of disk-type rewinding members while elevating and lowering the rotary motor, thereby drawing a support belt from the required disk-type rewinding member. Towel dyeing method, characterized in that it comprises a vertical transfer cylinder (3300) for drawing out. 6. The method of claim 5,
Polluted air measuring kit,
a tube member 3510 having a flow path formed therein;
a first filter 3520 disposed inside the tube member 3510;
a second filter 3530 spaced apart from the first filter 3520 and disposed inside the tube member 3510;
and a third filter (3550) spaced apart from the second filter (3530) and disposed inside the tube member (3510);
a first reactant 3540 reacting with the gas passing through the first filter 3520 is filled between the first filter 3520 and the second filter 3530;
A towel dyeing method, characterized in that between the second filter (3530) and the third filter (3550) is filled with a second reactant (3560) reacting with the gas that has passed through the second filter (3530).

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