KR20190142950A - Apparatus for sampling dye solution to analysis compatibility and method for sampling dye solution using the same - Google Patents

Abstract

According to an embodiment of the present invention, provided is a dye solution sampling apparatus capable of analyzing the color of a small amount (less than 10% in contrast to other dyes) of dye with the emphasis of the single color of the individual dye by adjusting an RGB filter penetration ratio, and making a compensation in accordance with the penetration ratio, thereby analyzing the concentration of the small amount of the individual dye in a mixed dye solution. According to an embodiment of the present invention, the dye solution sampling apparatus includes: a dye solution injection line providing a flow path in which a dye solution discharged from a dyeing part for dyeing an object flows; a dye solution analysis module combined with the dye solution injection line to receive the dye solution from the dye solution injection line, including a plurality of color filters which are optical filters to emphasize the color of dye in the dye solution, making the flowing dye solution flow through the color filters, and collecting a dye solution image which is an image of the dye solution; a dye solution discharge line combined with the dyeing part to provide a flow path leading the dye solution discharged from the dye solution analysis module to flow to the dyeing part; and an analysis part receiving the dye solution image from the dye solution analysis module, and analyzing the ratio of dye included in the dye solution based on the dye solution image.

Description

A saline sampling device for compatibility analysis and a saline sampling method using the same {APPARATUS FOR SAMPLING DYE SOLUTION TO ANALYSIS COMPATIBILITY AND METHOD FOR SAMPLING DYE SOLUTION USING THE SAME}

The present invention relates to a saline sampling device for compatibility analysis and a saline sampling method using the same. More specifically, the dye color entering a small amount (less than 10% compared to other dyes) by adjusting the RGB filter transmittance of the monochromatic color of the individual dye The present invention relates to a salt solution sampling apparatus capable of analyzing the concentration of individual dyes contained in a small amount of mixed salt solution by analyzing by highlighting and correcting by the transmittance thereof, and a salt solution sampling method using the same.

The conventional suction behavior and compatibility measuring devices all use a spectrometer as a basic device. The principle is that the absorption behavior and compatibility are calculated by calculating the amount of light emitted from the salt solution at a predetermined interval. Is measuring.

However, when dyeing a mixture of the three dyes at the site where the dyeing process is carried out, the dyeing prescription is mostly different from any one or two dyes rather than the same dye prescription. Therefore, when measuring the absorption behavior or compatibility of the salt solution having a large difference in the ratio between the dyes, dyes having a small ratio due to the high ratio of dyes cannot be accurately measured.

Specifically, in the case of a dye formulation on the spot mixing three or more, in the case of a formulation containing a small amount (less than 10% compared to other dyes), it is difficult to measure due to the other dyes, it is not possible to calculate the exact concentration. In this case, the two representative dyes are measured and the dyes in small amounts are calculated to calculate the concentration, but this is also not accurate, and the dye may be ignored at all.

In Korean Patent No. 10-1105463 (name of the invention: automatic salt dilution method using the same) and the automatic salt dilution method using the same, set the optimization conditions of the device according to the concentration and condition of the salt solution transferred to the dyeing curve automatic measuring device and set value A control system for controlling the optimization by transmitting a signal; A salt solution transfer and recovery system for sampling the salt solution transferred to the dyeing curve automatic measuring device according to the transmission data of the control system and recovering the remaining salt solution; An optimization system that makes the salt sample sampled in the salt transfer and recovery system optimally for stable and reproducible measurement according to the transmission data of the control system; Disclosed is a salt solution dilution device consisting of a measuring device conveying system for carrying out a conveying operation to a dyeing curve automatic measuring device after completion of optimization.

Republic of Korea Patent No. 10-1105463

An object of the present invention for solving the above problems, when dyeing a mixture of three dyes, the dye color that enters a small amount (less than 10% compared to other dyes) in the dyeing prescription where the ratio difference between the dyes is much It is to provide a device that enables it.

The technical problem to be achieved by the present invention is not limited to the technical problem mentioned above, and other technical problems not mentioned above may be clearly understood by those skilled in the art from the following description. There will be.

The constitution of the present invention for achieving the above object is a salt solution input line for providing a flow path through which the salt solution discharged from the dyeing unit performing the dyeing for the blood flow; It is provided with a plurality of color filters which are coupled to the salt input line and receives the salt solution from the salt input line, and highlights the color of the dye contained in the salt solution, the flowing salt solution passes through the color filter, A saline solution analysis module for collecting saline images that are images of saline solution; A salt solution discharge line coupled to the salt solution analysis module and the dyeing unit, and providing a flow path to allow the salt solution discharged from the salt solution analysis module to flow into the dyeing unit; And an analysis unit receiving the saline image from the saline solution analysis module and analyzing a ratio of the dye included in the saline solution using the saline image.

In an embodiment of the present invention, the salt solution analysis module, each provided with at least one or more analysis cells having a color filter, the salt solution input line and the salt solution discharge line is connected to the salt solution passes through the analysis cell, It may be provided with a salt solution analysis cell unit for changing the position of the analysis cell by performing a rotational movement, and an image sensor unit for imaging the salt solution image formed by the salt solution is transmitted through the color filter.

In an embodiment of the present invention, the salt solution analysis module is coupled to the salt analysis cell unit, the driving motor unit for rotating the salt analysis cell unit, and combined with the drive motor unit to cover the salt analysis cell unit, the image A cover portion coupled to the sensor portion may be further provided.

In an embodiment of the present invention, the salt solution analysis cell unit is provided with a transparent filter and an initial analysis cell in which an initial analysis flow path, which is a flow path through which the initial liquid passes, is provided with a red color filter which is a color filter transmitting red color. And a red analysis cell in which a red analysis flow path is formed, which is a passage through which the salt solution passes, and a yellow analysis cell having a yellow analysis filter as a passage through which the salt solution passes, and a red analysis cell having a yellow color filter as a color filter passing through the yellow solution. And a blue analysis cell including a blue color filter that is a color filter that transmits blue and a blue analysis flow path that is a flow path through which a salt solution passes.

In an embodiment of the present invention, the salt solution input line, the initial analysis channel, and the salt solution discharge line may be connected by the rotary motion of the salt analysis cell unit.

In an embodiment of the present invention, the salt solution input line, the red analysis channel, the yellow analysis channel, the blue analysis channel, and the salt discharge line may be connected by the rotational movement of the salt analysis cell unit.

In an embodiment of the present disclosure, the salt solution analysis module may further include a salt solution driving unit coupled to the salt solution discharge line and changing the position of the salt solution discharge line in a three-dimensional direction.

In an embodiment of the present invention, the salt solution discharge line may be coupled to the inlet of the salt solution discharge line and may be provided with a discharge sealing portion to prevent leakage of a portion where the inlet of the salt solution discharge line and the flow path of the analysis cell is connected. have.

In an embodiment of the present invention, the salt solution input line may be provided with an injection sealing portion that is coupled to the outlet of the salt solution input line and prevent leakage of a portion where the outlet of the salt solution input line and the flow path of the analysis cell is connected. have.

In an embodiment of the present invention, the color filter may be an optical filter whose color varies according to an applied voltage.

In an embodiment of the present disclosure, the display unit may further include a display unit that receives data on the ratio of the dye from the analysis unit and expresses a change in the ratio of the dye included in the salt solution in a graph and a numerical value.

According to one aspect of the present invention, the initial liquid discharged from the salt solution pump part flows along the salt solution input line, and then flows into the initial analysis cell so that the initial solution image is generated by the first image sensor. Imaging; ii) connecting the salt solution input line and the red analysis cell by rotating the salt analysis cell unit; iii) flowing the salt solution discharged from the dyeing unit while sequentially passing through the red analysis cell, the yellow analysis cell and the blue analysis cell; iv) imaging each of the salt solutions transmitted through the red color filter, the yellow color filter, and the blue color filter by the first image sensor, the second image sensor, and the third image sensor; And v) calculating the ratio of the dye in the saline solution by analyzing each saline image of the analysis unit.

Effect of the present invention according to the above configuration, in the dyeing prescription with a large difference in ratio between the dyes, the dye color entering a small amount (less than 10% compared to other dyes) by adjusting the RGB filter transmittance to highlight the monochromatic color of the individual dyes It is possible to analyze the concentration of individual dyes that enter a small amount in the mixed salt solution by analyzing the resultant and correcting it by the transmittance.

In addition, the effect of the present invention is that it is possible to analyze the concentration of individual dyes that enter a small amount in the mixed salt solution as described above, it is possible to contribute to the productivity and cost reduction by improving the dye reproducibility and color difference.

The effects of the present invention are not limited to the above-described effects, but should be understood to include all the effects deduced from the configuration of the invention described in the detailed description or claims of the present invention.

1 is a schematic diagram of a salt solution sampling apparatus according to an embodiment of the present invention.
2 is a front view of a salt solution analysis module according to an embodiment of the present invention.
Figure 3 is a schematic diagram of the configuration of the salt solution analysis module according to an embodiment of the present invention.
4 is a plan view of a salt solution analysis module according to an embodiment of the present invention.
5 is a schematic view of the salt analysis cell unit according to an embodiment of the present invention.
Figure 6 is a schematic diagram of the salt analysis cell unit according to another embodiment of the present invention.
7 is an image for comparison of the salt solution image according to the transmittance of each color filter according to another embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings will be described the present invention. As those skilled in the art would realize, the described embodiments may be modified in various different ways, all without departing from the spirit or scope of the present invention. In the drawings, parts irrelevant to the description are omitted in order to clearly describe the present invention, and like reference numerals designate like parts throughout the specification.

Throughout the specification, when a part is said to be "connected (connected, contacted, coupled) with another part, it is not only" directly connected "but also" indirectly connected "with another member in between. Includes the case where In addition, when a part is said to "include" a certain component, this means that it may further include other components, without excluding the other components unless otherwise stated.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. Singular expressions include plural expressions unless the context clearly indicates otherwise. As used herein, the terms "comprise" or "have" are intended to indicate that there is a feature, number, step, action, component, part, or combination thereof described on the specification, and one or more other features. It is to be understood that the present invention does not exclude the possibility of the presence or the addition of numbers, steps, operations, components, components, or a combination thereof.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

1 is a schematic view of a salt sampling apparatus according to an embodiment of the present invention, Figure 2 is a front view of the salt solution analysis module 10 according to an embodiment of the present invention, Figure 3 according to an embodiment of the present invention It is a schematic diagram of the structure of the salt solution analysis module 10. And, Figure 4 is a plan view of the salt solution analysis module 10 according to an embodiment of the present invention.

And, Figure 5 is a schematic diagram of the salt analysis cell unit 100 according to an embodiment of the present invention, Figure 6 is a schematic diagram of the salt analysis cell unit 100 according to another embodiment of the present invention.

As shown in Figures 1 to 6, the salt solution sampling apparatus of the present invention, the salt solution input line 410 for providing a flow path for the salt solution discharged from the dyeing unit 500 for performing the staining for the blood; Combined with the salt solution input line 410 receives the salt solution from the salt solution input line 410, and has a plurality of color filters that are optical filters that highlight the color of the dye contained in the salt solution, the flowing salt solution passes through the color filter A salt solution analysis module 10 for collecting a salt solution image which is an image of the salt solution; A salt solution discharge line 420 coupled to the salt solution analysis module 10 and the dyeing unit 500 and providing a flow path to allow the salt solution discharged from the salt solution analysis module 10 to flow into the dyeing unit 500; And an analysis unit 600 receiving the saline image from the saline solution analysis module 10 and analyzing the proportion of the dye contained in the saline solution using the saline image.

According to the above configuration, in dyeing formulations where there is a large difference in the ratio between dyes, the dye color entering a small amount (less than 10% of other dyes) is adjusted to transmit the monochromatic color of the individual dye by adjusting the transmittance of the color filter which is an RGB optical filter. By analyzing the amount of the dye, and correcting it by the transmittance, it is possible to analyze the concentration of individual dyes in a small amount in the salt solution mixed with a plurality of dyes.

The dyeing unit 500 is filled with the saline solution to perform dyeing for the chlorine, it may be provided with a saline pump unit 510. The dyeing pump 500 and the salt pumping unit 510 coupled to the salt solution input line 410 and the salt solution discharge line 420 provide hydraulic pressure to the salt solution of the dyeing unit 500 so that the salt solution of the dyeing unit 500 The saline solution flowing through the saline solution input line 410 is introduced into the saline solution analysis module 10, and provides hydraulic pressure to the saline solution discharged from the saline solution analysis module 10 to pass through the saline solution analysis module 10. Along the 420 may be introduced into the dyeing unit 500 again.

2 to 4, the salt solution analysis module 10 is provided with at least one or more analysis cells, each having a color filter, the salt solution input line 410 and the salt solution discharge line 420 is connected to the salt solution The saline solution cell unit 100 passes through the analysis cell and performs a rotational movement to change the position of the analysis cell, and an image sensor unit 200 for capturing the saline image formed by the salt solution passing through the color filter. can do.

In addition, the saline solution analysis module 10 is coupled to the saline analysis cell unit 100, the driving motor unit 310 for rotating the saline analysis cell unit 100, and the driving motor unit 310 and the saline analysis cell unit 100 ) And a cover unit 330 coupled to the image sensor unit 200 may be further provided.

As shown in FIG. 2, the image sensor unit 200 formed of a plurality of image sensors includes a first image sensor 210, a second image sensor 220, and a third image sensor 230. The image sensor may be fixedly supported by being coupled to the cover part 330. Each image sensor is coupled to a plurality of cover parts 330 perforations formed at positions corresponding to the positions of the respective analysis cells, so that the image sensor is exposed to the salt solution visually exposed through the color filter of the analysis cell. The saline image can be taken.

As shown in FIGS. 5 and 6, the salt analysis cell unit 100 includes an initial analysis cell 110 including a transparent filter 164 and an initial analysis flow path 111, which is a flow path through which an initial solution passes. A red analysis cell 120 having a red color filter 161 which is a color filter which transmits red and a red analysis flow passage 121 which is a flow path through which a salt solution passes, and a yellow color which is a color filter transmitting yellow And a yellow analysis cell 130 having a filter 162 and a yellow analysis flow passage 131 formed therein as a passage through which a salt solution passes, and a blue color filter 163 which is a color filter transmitting blue therein. It may be provided with a blue analysis cell 140, the blue analysis flow path 141 is a flow path for the salt solution is formed.

Each analysis cell has an analysis space formed therein, and the liquid passing through each analysis flow passage may be temporarily stored in the analysis space of the analysis cell and then flow. Specifically, the initial analysis cell 110 is formed in the initial analysis space connected to the initial analysis flow path 111, the red analysis cell 120 is formed in the red analysis space connected to the red analysis flow channel 121, yellow In the analysis cell 130, a yellow analysis space connected to the yellow analysis flow path 131 may be formed, and in the blue analysis cell 140, a blue analysis space connected to the blue analysis flow path 141 may be formed. Here, the salt solution (or the initial liquid) temporarily stored in each analysis space is transmitted through the color filter (or the transparent filter 164) so that imaging may be performed by each image sensor.

In the exemplary embodiment of the present invention, the salt input line 410, the red analysis channel 121, the yellow analysis channel 131, the blue analysis channel 141, and the salt solution line 420 are sequentially described. However, the present invention is not limited thereto, and the red analysis cell 120, the yellow analysis cell 130, and the blue analysis cell 140 are coupled to the analysis cell base 150 in a different arrangement order. The yellow analysis channel 131 and the blue analysis channel 141 may be connected to each other in a different arrangement order. However, in the following description of the present invention, for convenience of description, it will be described that each analysis cell is arranged and installed as shown in FIGS. 5 and 6.

2 and 5 and 6, the initial analysis cell 110 or the red analysis cell 120 may be selectively positioned in the installation position of the first image sensor 210, the first image sensor ( 210 may perform imaging on the salt solution transmitted through the transparent filter 164 or the red color filter 161.

In addition, when the salt solution passes through the yellow analysis cell 130, the yellow analysis cell 130 may be positioned at the installation position of the second image sensor 220, and the second image sensor 220 may be a yellow color filter ( Imaging may be performed on the salt solution transmitted through 162. In addition, when the salt solution passes through the blue analysis cell 140, the blue analysis cell 140 may be located at the installation position of the third image sensor 230, the third image sensor 230 is a blue color filter ( Imaging may be performed on the salt solution transmitted through 163.

The salt solution analysis module 10 may further include a salt solution driving unit 340 coupled to the salt solution discharge line 420 and changing the position of the salt solution discharge line 420 in a three-dimensional direction. And, the salt solution discharge line 420 is located between the dyeing unit 500 and the salt discharge drive unit 340, the fixed salt discharge line 422, and the salt solution coupled to the dyeing unit 500 and the salt discharge drive unit 340, and the salt solution The discharge driving unit 340 and the salt analysis cell unit 100 may be connected to the mobile salt solution discharge line 421 for providing a flow path to the salt solution discharged through the salt solution analysis cell unit 100.

The saline solution analysis cell unit 100 is coupled to at least one or more analysis cells and supports each analysis cell, and is coupled to the driving motor unit 310 to perform a rotational motion to rotate each analysis cell by rotating the analysis cell base 150. ) May be provided.

Each analysis cell coupled to the analysis cell base 150 formed in the shape of a cylinder may be formed in the shape of a cylinder, and one surface circular in the analysis cell base 150 is combined with the analysis cell and the analysis cell base 150. The other surface of the circular in the drive motor 310 can be coupled to.

In addition, the color filter is coupled to one circular surface of the analysis cell, and the other surface of the circular shape of the analysis cell is combined with one circular surface of the analysis cell base 150, and each analysis cell is rotated as the analysis cell base 150 rotates. An orbital motion may be performed such that the position is changed around the rotation axis of the analysis cell base 150.

As shown in FIG. 5, the salt solution input line 410, the initial analysis channel 111, and the salt solution discharge line 420 may be connected by the rotational movement of the salt analysis cell unit 100. Here, the inlet 111a of the initial analysis flow path provided in the initial analysis cell 110 is connected to the salt input line 410, and the outlet 111b of the initial analysis flow path is the mobile saline discharge line (420) of the salt discharge line (420). 421 may be connected. In addition, the mobile saline discharge line 421 may be connected to the outlet 111b of the initial analysis flow path by performing a three-dimensional movement by the saline discharge driving unit 340 to move to the position of the outlet 111b of the initial analysis flow path.

And, the salt solution pump unit 510 is combined with the water tank in which the water is stored to flow the initial liquid water to the salt solution input line 410, while the initial liquid flows along the initial analysis flow path 111, the initial analysis cell ( After passing through 110, it is discharged to the outlet 111b of the initial analysis flow path and can be discharged to the outside by flowing through the mobile saline discharge line 421, the saline discharge drive unit 340 and the fixed saline discharge line 422. have.

In addition, the initial analysis channel 111 is formed to pass through the transparent filter 164, the initial solution of the dyeing unit 500 passed through the salt solution input line 410 is the initial analysis channel 111 of the initial analysis cell 110 The initial liquid may be visually exposed through the transparent filter 164 while flowing through the filter. Accordingly, the first image sensor 210 may capture an initial liquid image, which is an image of the initial liquid captured by the transparent filter 164.

In addition, as shown in Figure 6, by the rotational movement of the salt analysis cell unit 100, the salt input line 410, red analysis flow channel 121, yellow analysis flow channel 131, blue analysis flow channel 141, and saline solution Discharge line 420 may be connected. Here, the inlet 121a of the red analysis channel provided in the red analysis cell 120 is connected to the salt input line 410, and the outlet 141b of the blue analysis channel provided in the blue analysis cell 140 discharges the salt solution. It may be connected to the mobile salt discharge line 421 of the line 420. Here, the mobile saline discharge line 421 may be connected to the outlet 111b of the initial analysis flow path by moving to the position of the outlet 111b of the initial analysis flow path by performing a three-dimensional movement by the saline discharge driving part 340.

Accordingly, the salt solution discharged from the dyeing unit 500 flows along the salt solution input line 410, and then sequentially flows along the red analysis channel 121, the yellow analysis channel 131, and the blue analysis channel 141. It is discharged through the mobile saline discharge line 421, and then, the saline solution may be circulated into the dyeing unit 500 by flowing through the saline discharge drive unit 340 and the fixed saline discharge line 422.

In addition, the red analysis flow passage 121 is formed to pass through the red color filter 161, the yellow analysis flow passage 131 is formed to pass through the yellow color filter 162, and the blue analysis flow passage 141 is the blue color filter. Is formed to pass through (163), the salt solution of the dyeing unit 500 passing through the salt solution input line 410 flows through the red analysis channel 121, the yellow analysis channel 131 and the blue analysis channel 141 In the meantime, the salt solution may be visually exposed through the red color filter 161, the yellow color filter 162, and the blue color filter 163. Accordingly, the first image sensor 210 may capture a red salt image, which is an image of the salt solution in which red filtering is performed, through the red color filter 161, and the second image sensor 220 may be a yellow color filter ( Through 162, a yellow saline image, which is an image of a saline solution with yellow filtering, may be captured, and the third image sensor 230 may be blue, which is an image of a saline solution with blue filtering, through the blue color filter 163. Salt image can be taken.

As described above, the mobile saline discharge line 421 moves in the three-dimensional direction according to the driving of the saline discharge drive unit 340, and thus the mobile saline discharge line 421 selectively selects the outlet 111b of the initial analysis flow path. ) May be connected to the outlet 141b of the blue analysis channel.

Here, the color filter may be an optical filter whose color varies according to an applied voltage. Accordingly, the transmittance of each color filter may be adjusted, and the transmittance of the curl filter may be adjusted according to the concentration of each dye.

In the embodiment of the present invention, it is described that each color filter is formed as an optical filter whose color varies according to the applied voltage, but is not necessarily limited thereto, and each color filter is manually replaceable, Each color filter can be replaced by changing the transmittance according to the type.

The salt solution analysis module 10 includes a salt solution analysis controller 320 coupled to the driving motor unit 310, and the salt solution analysis controller 320 is connected to each image sensor to capture a salt image captured by each image sensor. Collected and transmitted to the analysis unit 600, the salt solution analysis control unit 320 is connected to each color filter may receive a user input to control the transmittance of each color filter. Here, the user input is a transmittance value for each color filter, and the user input is directly input to an input device provided in the salt analysis controller 320 or is inputted by an external device such as a smart phone, and the corresponding value is input to the salt solution analysis controller. And may be delivered to 320. In addition, the transmittance of each color filter may be changed by the salt solution analysis controller 320 at predetermined time intervals, and thus, each salt image may be collected at predetermined time intervals.

5 and 6, the salt discharge line 420 is coupled to the inlet of the salt discharge line 420, and prevents leakage of a portion where the inlet of the salt discharge line 420 and the flow path of the analysis cell is connected. A discharge seal 423 may be provided. And, the salt input line 410, the input sealing portion 411 is coupled to the outlet of the salt input line 410 and prevents leakage of the portion where the outlet of the salt input line 410 and the flow path of the analysis cell is connected. It can be provided.

When the sealing unit 411 is connected to the initial analysis cell 110 or the red analysis cell 120, the surface of the analysis cell such that the portion of the input sealing unit 411 in contact with the analysis cell is in close contact with the surface of the analysis cell. It may be formed in a curved surface corresponding to the shape of the. Similarly, the discharge sealing unit 423 corresponds to the shape of the surface of the analysis cell such that the portion of the discharge sealing unit 423 in contact with the analysis cell is in close contact with the surface of the analysis cell when connected to the blue analysis cell 140. It may be formed into a curved surface.

In addition, the inlet sealing unit 411 and the discharge sealing unit 423 may be formed of a material having elasticity and elasticity such as silicone, synthetic resin, rubber, and the like, thereby increasing the efficiency of adhesion as described above. Accordingly, leakage of the initial liquid or salt solution introduced into the saline solution cell unit 100 from the saline solution input line 410 may be prevented. In addition, leakage of the initial liquid or the salt solution discharged from the salt analysis cell unit 100 to the salt solution discharge line 420 may be prevented.

Hereinafter, the matter of performing the saline analysis by the analysis of the analysis unit 600 for each image will be described.

As described above, before performing the analysis on the saline solution of the dyeing unit 500, the initial liquid image which is an image of the initial liquid may be transferred to the analysis unit 600. While the initial liquid, which is pure water, passes through the transparent filter 164 of the initial analysis cell 110, the initial liquid image captured by the first image sensor 210 is analyzed, and the analyzer 600 analyzes the salt solution. The surrounding environment of the salt solution analysis cell unit 100 may be analyzed. Specifically, the liquid passing through the salt analysis cell unit 100 by the light of the surrounding environment of the salt analysis cell unit 100 can be analyzed whether the color of any one of red, yellow or blue, using the salt image The analysis data can be corrected.

7 is an image of a comparison of the salt image according to the transmittance of each color filter according to another embodiment of the present invention. In FIG. 7, the images arranged in the middle row (column b) are a plurality of yellow saline images showing the incidence of yellow according to the transmittance of the yellow color filter 162, and the left column (column a) of the yellow saline image is a plurality of images. The red saline image and the right column (column b) of the yellow saline image are a plurality of blue saline images. Here, each% value may represent a transmittance.

As shown in FIG. 7, the red color filter 161 may highlight red, the yellow color filter 162 may highlight yellow, and the blue color filter 163 may highlight blue. And, as shown in the example of the red color filter 161, the degree to which the red color filter 161 highlights the red color of the red dye according to each transmittance is different, the salt solution by analyzing the red saline image according to each transmittance The ratio of the red dye can be calculated.

In detail, a red sharpness difference generated by each red color filter 161 is generated according to the transmittance of each red color filter 161, and the distribution value of the red sharpness difference is based on the ratio of the red dye in the salt solution. It can be different according to the distribution, the ratio of the red dye in the salt solution can be derived by the distribution value of the sharpness difference of red. Further, the red dye analysis data, which is data on the ratio of the red dye in the salt solution according to the distribution value of the sharpness difference of red, may be prepared in advance and stored in the analysis unit 600, and the analysis unit 600 may analyze the red dye analysis data. Red dye image can be used to calculate the ratio of red dye in salt solution.

The same principle applies to the case of deriving the ratio of the yellow dye in the salt solution using the yellow color filter 162, and the same as the case of deriving the ratio of the blue dye in the salt solution using the blue color filter 163. Can be.

The salt solution sampling apparatus of the present invention may further include a display unit 700 which receives data on the ratio of the dye from the analyzer 600 and expresses the change in the ratio of the dye included in the salt solution in graphs and numerical values.

The analyzer 600 stores the types of dyes (red dye, yellow dye, and blue dye) mixed in the saline solution in advance, and analyzes the ratio of each dye in the saline solution in real time. ) Can express the ratio of each dye in the saline solution analyzed in real time as a graph and a numerical value on the screen.

The dyeing process system including the salt solution sampling device of the present invention can be constructed. Then, the fabric production system including the salt solution sampling apparatus of the present invention can be constructed.

Hereinafter, a salt solution sampling method using the salt solution sampling apparatus of the present invention will be described.

In the first step, the initial liquid discharged from the salt solution pump 510 flows along the salt solution input line 410 and then flows into the initial analysis cell 110 to capture the initial solution image by the first image sensor 210. Can be.

In the second step, the salt analysis cell unit 100 may be rotated to connect the salt solution input line 410 and the red analysis cell 120.

In the third step, the salt solution discharged from the dyeing unit 500 may flow while sequentially passing through the red analysis cell 120, the yellow analysis cell 130, and the blue analysis cell 140.

In a fourth step, the red color filter 161, the yellow color filter 162, and the blue color filter 163 are formed by the first image sensor 210, the second image sensor 220, and the third image sensor 230. Each transmitted saline image can be imaged.

In a fifth step, the analysis unit 600 may calculate the ratio of the dye in the saline solution by analyzing each saline image.

The foregoing description of the present invention is intended for illustration, and it will be understood by those skilled in the art that the present invention may be easily modified in other specific forms without changing the technical spirit or essential features of the present invention. will be. Therefore, it should be understood that the embodiments described above are exemplary in all respects and not restrictive. For example, each component described as a single type may be implemented in a distributed manner, and similarly, components described as distributed may be implemented in a combined form.

The scope of the present invention is represented by the following claims, and it should be construed that all changes or modifications derived from the meaning and scope of the claims and their equivalents are included in the scope of the present invention.

10: salt solution analysis module 100: salt solution cell unit
110: initial analysis cell 111: initial analysis euro
111a: entrance to the initial analysis flow path 111b: exit to the initial analysis flow path
120: red analysis cell 121: red analysis euro
121a: entrance to the red analysis channel 130: yellow analysis cell
131: yellow analysis channel 140: blue analysis cell
141: blue analysis channel 141b: blue analysis channel exit
150: analysis cell base 161: red color filter
162: yellow color filter 163: blue color filter
164: transparent filter 200: image sensor
210: first image sensor 220: second image sensor
230: third image sensor 310: drive motor unit
320: salt solution analysis control unit 330: cover part
340: salt discharge drive unit 410: salt injection line
411: sealing unit 420: salt discharge line
421: mobile saline discharge line 422: fixed saline discharge line
423: discharge seal portion 500: dyeing portion
510: salt solution pump 600: analysis unit
700: display unit

Claims (14)

A salt solution input line for providing a flow path through which the salt solution discharged from the dyeing unit performing staining on the blood stain flows;
It is provided with a plurality of color filters which are coupled to the salt input line and receives the salt solution from the salt input line, and highlights the color of the dye contained in the salt solution, the flowing salt solution passes through the color filter, A saline solution analysis module for collecting saline images that are images of saline solution;
A salt solution discharge line coupled to the salt solution analysis module and the dyeing unit, and providing a flow path to allow the salt solution discharged from the salt solution analysis module to flow into the dyeing unit; And
Receiving the saline image from the saline solution analysis module, Analysis unit for analyzing the ratio of the dye contained in the saline solution using the saline solution; Salt solution sampling device for comprising a.
The method according to claim 1,
The salt solution analysis module,
Each saline solution includes at least one analysis cell having a color filter, and the saline solution input line and the saline solution discharge line are connected to each other so that the saline solution passes through the analysis cell, and rotates to change the position of the analysis cell. An analysis cell unit, and
And an image sensor unit for photographing the salt image formed by the salt solution being transmitted through the color filter.
The method according to claim 2,
The salt solution analysis module,
A driving motor unit coupled to the saline analysis cell unit to rotate the saline analysis cell unit, and
And a cover part coupled to the driving motor part to cover the saline solution analysis cell part and to be coupled to the image sensor part.
The method according to claim 2,
The saline solution cell unit,
An initial analysis cell having a transparent filter and having an initial analysis flow path formed therein;
A red analysis cell having a red color filter, which is a color filter transmitting red color, and a red analysis flow channel, which is a flow path through which a salt solution passes,
A yellow analysis cell having a yellow color filter which is a color filter which transmits yellow color, and a yellow analysis flow path which is a flow path through which a salt solution passes, and
And a blue analysis cell having a blue color filter, which is a color filter which transmits blue, and a blue analysis flow path being a flow path through which the salt solution passes.
The method according to claim 4,
The salt solution sampling device for compatibility analysis, characterized in that the salt input line, the initial analysis flow path, and the salt discharge line is connected by the rotational movement of the salt analysis cell unit.
The method according to claim 4,
And the salt input line, the red analysis channel, the yellow analysis channel, the blue analysis channel, and the salt discharge line are connected by a rotational movement of the salt analysis cell unit.
The method according to claim 4,
The salt solution analysis module is coupled to the salt discharge line, and the salt solution sampling apparatus for compatibility analysis further comprising a salt discharge drive unit for changing the position of the salt discharge line in the three-dimensional direction.
The method according to claim 7,
The saline solution discharge line is coupled to the inlet of the saline solution discharge line, and the saline solution for compatibility analysis characterized in that it comprises a discharge sealing portion for preventing leakage of the portion connected to the inlet of the saline solution discharge line and the analysis cell flow path Sampling device.
The method according to claim 4,
The saline solution input line is coupled to the outlet of the saline solution input line, and the saline solution for compatibility analysis characterized in that it comprises an injection sealing portion to prevent leakage of the portion where the outlet of the saline input line and the flow path of the analysis cell is connected. Sampling device.
The method according to claim 1,
The color filter is a salt sampling device for compatibility analysis, characterized in that the color of the optical filter is variable according to the applied voltage.
The method according to claim 1,
And a display unit for receiving data on the ratio of the dye from the analysis unit and displaying a change in the ratio of the dye included in the salt solution in graphs and numerical values.
A dyeing process system comprising a salt sampling apparatus for compatibility analysis according to any one of claims 1 to 11.
A fabric production system comprising a salt sampling apparatus for compatibility analysis according to any one of claims 1 to 11.
In the salt sampling method using the salt sampling device for compatibility analysis of claim 4,
i) the initial liquid discharged from the salt solution pump unit flows along the salt solution input line and then flows into the initial analysis cell to capture the initial liquid image by the first image sensor;
ii) connecting the saline solution input line and the red analysis cell by rotating the saline solution cell unit;
iii) flowing the salt solution discharged from the dyeing unit while sequentially passing through the red analysis cell, the yellow analysis cell and the blue analysis cell;
iv) imaging each of the salt solutions transmitted through the red color filter, the yellow color filter, and the blue color filter by the first image sensor, the second image sensor, and the third image sensor; And
and v) calculating the ratio of the dye in the saline solution by analyzing the respective saline images of the analysis unit.

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