KR101645168B1 - liquid sample analysis device and method using optical density - Google Patents

Abstract

Disclosed is an apparatus and method for analyzing a liquid sample using absorbance. A lower transparent glass disposed on the upper surface of the liquid sample, an upper transparent glass for pressing and spreading the disposed liquid sample on the side, a rotation protrusion for adjusting the height of the upper transparent glass, and the rotation protrusion, A support for supporting the upper transparent glass, and a controller for calculating an absorbance at a reference thickness on the basis of a predetermined reference thickness of the lower transparent glass and the upper transparent glass, and based on the calculated absorbance, And a control unit for calculating the output value.

Description

TECHNICAL FIELD The present invention relates to a liquid sample analyzing apparatus and a liquid sample analyzing method using the same,

The present invention relates to a liquid sample analyzer, and more particularly, to a liquid sample analyzer using absorbance and a method thereof.

In recent years, in order to estimate the concentration of solute in high concentration liquid samples, especially dark substances, the light amount is measured by using a spectrophotometer and a photo-densitometer instead of using a chemical reaction. A method of measuring absorbance or transmittance is widely used.

In particular, the method of measuring the concentration of the solute by diluting a very small amount of the solution has the disadvantage that the dilution procedure accompanies the troublesomeness and the result may be inaccurate. That is, in the case of a liquid sample having a small water droplet, since the amount thereof is very small as in the range of about 3 to 5 mg, it is difficult to accurately determine the concentration of the solute in the dilution. Thus, the diluted concentration also has the disadvantage that the inaccuracy can become large.

Spectrophotometers such as spectrophotometers, photo densitometers and laser densitometers are very expensive, and when a liquid sample is placed in a cuvette, the amount of sample must be at least a certain amount. In addition, since the path length in the cuvette into which the sample is placed is a certain length, the light intensity of the lamp may hardly reach the sensor in order to measure optical density, absorbance, and transmittance in a dark sample at a high concentration. In this case, the accuracy of the absorbance is very poor, and there is a disadvantage in that an error of the measured value becomes larger as the concentration becomes darker.

Therefore, studies on a method for overcoming the above problems have been made.

Korean Patent No. 10-1027762 relates to an in-liquid sample analysis method which can easily and surely prevent the evaporation of analytical liquid using a scanning probe microscope or a cantilever sensor.

Disclosure of Invention Technical Problem [8] The present invention provides a liquid sample analyzing apparatus using absorbance that detects a large amount of absorbance measurement data of a two-dimensionally widely dispersed liquid by adjusting the thickness of a liquid sample so that a small amount of liquid sample is dispersed over a wide area And a method thereof.

Another object of the present invention is to provide an apparatus and method for analyzing a liquid sample using an absorbance which facilitates measurement of absorbance by increasing light transmittance of a liquid sample.

Another object of the present invention is to provide an apparatus and method for analyzing a liquid sample using absorbance to calculate the solute content of a liquid sample using the thickness, mass, and density of the liquid sample.

The apparatus for analyzing a liquid sample using absorbance according to the present invention comprises:

A lower transparent glass disposed on the upper surface of the liquid sample, an upper transparent glass for spreading the disposed liquid sample on the side, a rotation protrusion for adjusting the height of the upper transparent glass to maintain the thickness of the liquid sample at a predetermined thickness, A support for supporting the lower transparent glass and the upper transparent glass, a light source for irradiating the liquid sample with light, a two-dimensional optical analyzer for measuring an optical density of the irradiated liquid sample, And a control unit for calculating the amount of solute using a relational equation between a predetermined absorbance and a mass ratio based on the measured absorbance.

And the lower transparent glass and the upper transparent glass are kept parallel to each other.

The rotation protrusion rotates by 360 degrees. When the rotation protrusion rotates clockwise, the height of the upper transparent glass increases. When the rotation protrusion rotates counterclockwise, the height of the upper transparent glass decreases.

The support portion includes a first support portion supporting the upper transparent glass and including a male screw, and a second support portion supporting the lower transparent glass and including a female screw.

The rotation protrusion is characterized by adjusting the height of the upper transparent glass in units of micrometers (占 퐉) by 1/360 mm when the interval between the female screws is 1 mm.

The first support portion is characterized in that the male screw is connected to the rotation projections and interlocked with each other.

Wherein the controller calculates the mass ratio (W / W fraction) based on the measured absorbance and then calculates the amount of solute using the following equation.

[Mathematical Expression]

은 액체시료에 대한 용질의 질량을 의미하고,

은 액체시료에 대한 시료의 질량을 의미하며,

는 시료에서 차지하는 용질의 질량비를 의미한다.
here,

Means the mass of the solute for the liquid sample,

Means the mass of the sample with respect to the liquid sample,

Means the mass ratio of the solute to the sample.

In another liquid sample analyzing apparatus according to the present invention,

A lower transparent glass disposed on the upper surface of the liquid sample, an upper transparent glass for spreading the disposed liquid sample on the side, a rotation protrusion for adjusting the height of the upper transparent glass, and the rotation protrusion, A support for supporting the upper transparent glass, and a controller for calculating an absorbance at a reference thickness on the basis of a predetermined reference thickness of the lower transparent glass and the upper transparent glass, and calculating an amount of a solute for the liquid sample based on the calculated absorbance And a control unit for calculating the output value.

The control unit calculates the absorbance at the reference thickness using the following equation.

Where OD _ref is the absorbance of the liquid sample at the reference thickness, t _ref is the reference thickness of the liquid sample, t _meas is the current thickness of the liquid sample, OD _meas is the absorbance of the liquid sample currently measured .

And the control unit calculates the amount of solute in the liquid sample using the relational expression of the calculated absorbance and a predetermined ratio of the absorbance to the mass ratio.

The method of analyzing a liquid sample using absorbance according to the present invention comprises:

Placing the liquid sample on the upper surface of the lower transparent glass; pressing the disposed liquid sample with the upper transparent glass to spread it laterally; maintaining the upper transparent glass at a predetermined height; irradiating the liquid sample with light Measuring an optical density of the irradiated liquid sample, and calculating an amount of the solute using a relationship between a predetermined absorbance and a mass ratio based on the measured absorbance.

The apparatus and method for analyzing a liquid sample using the absorbance according to the present invention detect a large amount of absorbance measurement data of two-dimensionally widely dispersed liquid by adjusting the thickness of a liquid sample such that a small amount of liquid sample is dispersed over a wide area .

In addition, the light transmittance to the liquid sample is increased to facilitate the measurement of the absorbance.

The solute content of the liquid sample is calculated using the thickness, mass, and density of the liquid sample.

Unlike conventional spectroscopic analyzers, a small amount of liquid sample is analyzed at low cost.

1 is a block diagram illustrating a liquid sample analyzer according to an embodiment of the present invention.
2 is a plan view for explaining a liquid sample analyzer according to an embodiment of the present invention.
3 is a cross-sectional view illustrating a liquid sample analyzer according to an embodiment of the present invention.
4 is an exploded view for explaining a liquid sample analyzer according to an embodiment of the present invention.
5 is a view for explaining a shape variation of a liquid sample according to an embodiment of the present invention.
FIG. 6 is a diagram realizing the diagram of FIG.
FIG. 7 is a view for explaining a result of measuring absorbance of a liquid sample according to an embodiment of the present invention by varying the content of a solute. FIG.
8 is a view for explaining scanning of a liquid sample according to the first embodiment of the present invention.
9 is a view for explaining a case where the liquid sample according to the second embodiment of the present invention is installed with a non-uniform thickness.
10 is a flowchart for explaining a method of measuring a small-amount high-concentration liquid sample according to the first embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the drawings, the same reference numerals as used in the appended drawings denote like elements, unless indicated otherwise. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather obvious or understandable to those skilled in the art.

1 is a block diagram illustrating a liquid sample analyzer according to an embodiment of the present invention. 1 (a) is a view for explaining a state in which the liquid sample 110 is not spread to the side, and Fig. 1 (b) is a view for explaining the measurement of the absorbance after the liquid sample 110 spreads to the side to be.

1 (a) and 1 (b), the liquid sample analyzer 1 includes an upper transparent glass 120, a lower transparent glass 130, a light source 140, a two-dimensional optical analyzer 150, .

The upper transparent glass 120 spreads the liquid sample 110 on the lower surface of the upper transparent glass 120 and the liquid sample 110 laterally through the height adjustment. The upper transparent glass 120 can transmit light through the transparent glass and may be free from warping.

The lower transparent glass 130 places the liquid sample 110 on the upper surface. The lower transparent glass 130 is fixed so as not to move when the liquid sample 110 spreads to the side. In addition, the lower transparent glass 130 may be made of transparent glass like the upper transparent glass 120, and may be free from warping.

The light source 140 irradiates the liquid sample 110 with light in order to confirm the absorbance of the liquid sample 110 with a light emitting object or a tool. The light source 140 may be any one of a tungsten lamp, a tungsten halogen lamp, a fluorescent lamp, an HMI lamp, a carbon arc lamp, a flash, a strobe light, a handheld lamp and a reflector.

The two-dimensional optical analyzer 150 measures the absorbance of the liquid sample 110 with respect to the light emitted from the light source 140. The two-dimensional optical analyzer 150 is a planar light transmission type analyzer, which can more easily calculate the concentration of the liquid sample.

The controller 160 controls the first half of the liquid sample analyzer 1. In particular, the controller 160 analyzes the liquid sample 110 by calculating the volume, density, and amount of solute based on the absorbance of the liquid sample 110.

The liquid sample analyzer 1 maintains a predetermined thickness by pressing a small amount of the liquid sample 110 and measures the absorbance through the liquid sample 110 to calculate the amount of the solute contained in the liquid sample 110.

The liquid sample analyzer 1 makes contact between the upper transparent glass 120 and the lower transparent glass 130 on the upper and lower sides of the liquid sample 110. When the liquid sample 110 touches both sides of the upper transparent glass 120, 120 and the lower transparent glass 130 by themselves. Due to the cohesive force of the liquid sample 110, the liquid sample 110 receives force upward and downward and spreads laterally. Here, the upward and downward force can be generated by the cohesive force of the liquid sample 110 and the capillary effect.

The liquid sample analyzer 1 disperses a small amount of the liquid sample 110 widely and uniformly through the development and the gap between the upper transparent glass 120 and the lower transparent glass 130 is equal to the thickness of the liquid sample 110 . The liquid sample analyzer 1 can measure the amount of light generated from the light source 140 with a greater intensity by adjusting the interval. Also, the liquid sample analyzer 1 can detect a large amount of data from an image scanned by the two-dimensional optical analyzer 150 due to the effect of enlarging the area of the liquid sample 110. The detected data analyzes the liquid sample 110 more accurately and precisely through the control unit 160.

FIG. 2 is a plan view for explaining a liquid sample analyzer according to an embodiment of the present invention, FIG. 3 is a sectional view for explaining a liquid sample analyzer according to an embodiment of the present invention, FIG. FIG. 5 is an exploded view for explaining a liquid sample analyzing apparatus according to an embodiment.

2 to 4, the liquid sample analyzer 1 includes an upper transparent glass 120, a lower transparent glass 130, a rotation protrusion 210, and a support 220.

The descriptions of the upper transparent glass 120 and the lower transparent glass 130 are not repeated because they have been described above.

The rotation protrusion 210 adjusts the height of the upper transparent glass 120 to maintain the thickness of the liquid sample 110 at a predetermined thickness. When the rotary protrusion 210 rotates in the clockwise direction at this time, the height of the upper transparent glass 120 increases, and when the counterclockwise rotation is performed, the height of the upper transparent glass 120 decreases . That is, the rotation protrusion 210 is adjustable in height while rotating along the female thread 325 of the second support part 320, which will be described later, and has a scale according to the rotating direction.

When the distance between the internal threads 325 of the second support part 320 is 1 mm, the height of the upper transparent glass 120 is 1/360 mm when the rotation protrusion 210 rotates by 1 °, .

The supporting part 120 includes a rotation protrusion 210 and supports the upper transparent glass 120 and the lower transparent glass 130. The supporting part 120 includes an angular scale 221 in which a scale such as a vernier caliper is shifted by a ratio of 9/10. This means that the angle can be adjusted to 1/10 °.

The supporting part 120 supports the upper transparent glass 120 and supports the first supporting part 310 including the male screw 315 and the second supporting part 320 supporting the lower transparent glass 130 and including the female screw 325, .

Specifically, the first support portion 310 includes a first glass support jaw 222, a second glass support jaw 223, a third glass support jaw 224, and a fourth glass support jaw 225, Thereby supporting the transparent glass 120. At this time, the upper transparent glass 120 receives the force to be pulled down due to the cohesive force as soon as it touches the liquid sample 110, so that the upper transparent glass 120 is positioned above the first to fourth glass base jaws 222, 223, 224, Can be stabilized.

Here, the first supporting part 310 may further include a tweezer groove 226 to facilitate the replacement of the upper transparent glass 120.

5 is a view for explaining a shape variation of a liquid sample according to an embodiment of the present invention. Fig. 5 (a) is a view for explaining the shape of a droplet without spreading the liquid sample, and Fig. 5 (b) is a diagram for explaining a spread form of the liquid sample.

FIG. 6 is a diagram realizing the diagram of FIG. FIG. 6A is a diagram realizing the drawing of FIG. 5A, and FIG. 6B is a diagram actually embodying the drawing of FIG. 5B.

5 and 6, the liquid sample analyzer 1 spreads a small amount of the liquid sample 110 widely, thereby facilitating the measurement of the absorbance.

The liquid sample analyzer 1 naturally forces the upper transparent glass 120 downward by the cohesive force of the liquid sample 110. At this time, the liquid sample analyzer 1 adjusts the thickness of the liquid sample 110 by the support part 220 supporting between the upper transparent glass 120 and the lower transparent glass 130, thereby spreading the liquid sample 110 uniformly.

Therefore, the liquid sample analyzing apparatus 1 makes it easy to measure the absorbance by maintaining the liquid sample 100 at a uniform thickness.

FIG. 7 is a view for explaining a result of measuring absorbance of a liquid sample according to an embodiment of the present invention by varying the content of a solute. FIG.

Referring to FIG. 7, the controller 160 may calculate the content of the solute contained in the liquid sample 110 by applying the predetermined relationship based on the measured absorbance of the liquid sample 110.

The control unit 160 uses a relational expression of the concentration and the absorbance calculated by measuring the concentrations or mass ratios of the liquid sample 110 stored in the storage unit (not shown) or a relationship between the mass ratio and the absorbance. The control unit 160 calculates the absorbance of the liquid sample 110 in which the concentration or the mass ratio is not known.

Here, the relational expression between the concentration and the absorbance stored in the storage section or the relational expression between the mass ratio and the absorbance is a relational expression calculated from the data measured and experimented at a constant thickness.

(Example)

7 is a graph showing the results of measuring the absorbance by varying the content of solute in a specific liquid sample (brown black powder). Here, the net optical density is used in a more precise manner. The ultimate absorbance is the absorbance calculated by subtracting the absorbance of a pure solvent containing no solute. Here, when the graph is plotted using the ultimate absorbance, since the absorbance of a sample to which no amount of solute is added can be represented as 0, the absorbance curve can be more accurately expressed with respect to the content of the solute.

First, the liquid sample analyzer 1 measures the absorbance only with a pure solvent to which no solute is added. The absorbance is then measured by varying the amount of liquid sample added. The absorbance is calculated by the following equation (1).

는 알짜 흡광도를 의미하고,

는 측정하고자 하는 용질을 포함하는 용액(solution) 의 흡광도 값을 의미하며,

는 용질을 포함하지 않는 순수한 용매(solvent)의 흡광도 값을 의미한다.
here,

Quot; refers to the absorbance of pure water,

Refers to the absorbance value of a solution containing a solute to be measured,

Quot; means the absorbance value of a pure solvent that does not contain a solute.

및

는 각각 [수학식 2] 및 [수학식 3]으로 정의된다.remind

And

Are defined by [Expression 2] and [Expression 3], respectively.

는 용액을 지난 후, 분석광의 세기를 의미하고,

는 용액을 지나기 전, 분석광의 세기를 의미하며,

는 용매를 지난 분석광의 투과도 값을 의미한다.
here,

Means the intensity of the analytical light after passing through the solution,

Means the intensity of the analysis light before passing through the solution,

Means the transmittance value of the analysis light passing through the solvent.

는 용액을 지난 후, 분석광의 세기를 의미하고,

는 용액을 지나기 전, 분석광의 세기를 의미하며,

는 용액을 지난 분석광의 투과도 값을 의미한다.
here,

Means the intensity of the analytical light after passing through the solution,

Means the intensity of the analysis light before passing through the solution,

Means the transmittance value of the analyzed light passing through the solution.

The liquid sample analyzer 1 calculates the absorbance value using the transmittance value, and calculates the absorbance value using the intensity value. When receiving the scanned image by the two-dimensional optical analyzer 150, the liquid sample analyzer 1 detects the intensity from the received image and calculates the absorbance value.

That is, if [Equation 1] is expressed again as an intensity value, it can be expressed as [Equation 4].

If the light source 140 of the liquid sample analyzer 1 outputs the intensity of the analysis light almost constantly during each measurement, it can be defined as an approximate value as shown in Equation (5).

와

를 소거시키면, [수학식 6]과 같이 수학식을 정리할 수 있다.
Therefore, in Equation 4,

Wow

The mathematical expression can be summarized as shown in Equation (6).

As a result, the liquid sample analyzer 1 calculates the net absorbance value using Equation (6).

The liquid sample analyzer 1 can define the relationship between the calculated net absorbance and the amount of the liquid sample. Whereby the liquid sample analyzer 1 can calculate the relational expression for the relationship.

Finally, the liquid sample analyzer 1 can calculate the concentration of the liquid sample using the calculated relational expression.

(First Experimental Example)

8 is a view for explaining scanning of a liquid sample according to the first embodiment of the present invention. Specifically, Fig. 8 is a graph showing an experiment showing the relationship between mass ratio (f) and albumin absorbance.

Referring to FIG. 8, as a two-dimensional optical analyzer, a liquid sample was scanned using an Epson professional 10000 XL flatbed scanner.

Here, as can be seen from the liquid sample indicated by the dotted line, this method has the advantage that all the areas of the liquid sample can be used as data necessary for converting the absorbance. In the conventional spectrometer transmission method, there is a disadvantage that data is taken only as a result between the incident beam and the passed beam.

For example, in the case of a small amount of 20 mg of high-concentration liquid sample, the dilution procedure or other method should be carried out since it is very small in the cuvette for spectral analysis. In addition, since these methods are one-dimensional analysis, there is a disadvantage that only one data can be obtained in one analysis.

However, when the present invention is used, 22 mg of a small amount of liquid sample can be widely dispersed in an area of about 20 cm 2. In particular, when an image is obtained at a resolution of 2400 dpi using a scanner, it is possible to detect about 1.8 × 10 ⁷ data, and more accurate values can be predicted by using statistics of all the detected data.

First, the area of the liquid sample was calculated by using an image tool or the like. For example, if the resolution at scanning is 2400 dpi and the number of pixels occupied by the image of the sample solution in the obtained image is 1.785 × 10 ⁷ , the length of 1 px is 1/2400 dpi = 25.4 / 2400 mm and the area of 1 px is 25.4 / 2400) ² mm ² , the area of the liquid sample is calculated as 1.785 × 10 ⁷ × (25.4 / 2400) ² mm ² = 1999.32 mm ² = 19.99 cm ² .

Next, the total volume of the liquid sample was calculated based on the calculated area and the thickness of the liquid sample (volume = area x thickness). When the mass of the liquid sample is m, the density of the liquid sample is calculated using the following equation (7).

는 액체시료의 밀도를 의미하고,

은 액체시료의 질량을 의미하며,

는 액체시료의 부피를 의미하고,

는 액체시료의 면적을 의미하며,

는 액체시료의 두께 평균을 의미한다.
here,

Means the density of the liquid sample,

Means the mass of the liquid sample,

Means the volume of the liquid sample,

Means the area of the liquid sample,

Means the average thickness of the liquid sample.

Lastly, the solubility mass was calculated by applying the absorbance information of the image obtained from the scanner to the relational expression calculated using the graph prepared based on the preliminary experiment (FIG. 7) as shown in [Equation 10].

Here, the user can arbitrarily determine the absorbance-mass ratio relation, and in this experiment, the absorbance-mass ratio relation is defined as [Equation 8].

는 알짜 흡광도를 의미하고,

,

는 임의의 변수를 의미하며,

는 질량비

를 의미한다.here,

Quot; refers to the absorbance of pure water,

,

Quot; means an arbitrary variable,

The mass ratio

.

에 대하여 정리를 하여 이미지로부터 얻은 알짜 흡광도를 산출하였고, 산출된 알짜 흡광도를 기초로 미지의 시료에 대한 질량비를 [수학식 9]와 같이 산출하였다.
[Equation 8]

And a mass ratio of the unknown sample to the unknown sample was calculated as shown in Equation (9) based on the calculated albumin absorbance.

은 액체시료에 대한 용질의 질량을 의미하고,

은 액체시료에 대한 시료의 질량을 의미하며,

는 시료에서 차지하는 용질의 질량비를 의미한다.here,

Means the mass of the solute for the liquid sample,

Means the mass of the sample with respect to the liquid sample,

Means the mass ratio of the solute to the sample.

That is, the amount of the solute contained in the liquid sample was calculated through the above-mentioned equation (10).

(Second Experimental Example)

9 is a view for explaining a case where the liquid sample according to the second embodiment of the present invention is installed with a non-uniform thickness. Fig. 9 (a) is a view showing a nonuniform thickness of a liquid sample, and Fig. 9 (b) is a plan view of the liquid sample of Fig. 9 (a).

9, when the thickness of the liquid sample 110 is uneven, that is, when it is difficult to define the accurate thickness t of the current liquid sample, The amount of solute in the liquid sample 110 was calculated.

Here, when the solute of the liquid sample 110 is not evenly distributed, it can be considered that the thickness of the liquid sample 110 is uneven.

Using the linear attenuation coefficient, the absorbance of the liquid sample 110 at the reference thickness is calculated, and the amount of the solute contained in the liquid sample 110 is calculated using the calculated absorbance .

The linear attenuation coefficient was calculated using Equations (11) to (15).

는 데이터의 총 개수를 의미하고,

는 각 지점마다의 액체시료의 두께를 의미하며,

는 액체시료의 평균 두께를 의미하고,

는 투과도(transmission)값을 의미하며,

는 선형 감쇠계수를 의미한다.
here,

Means the total number of data,

Means the thickness of the liquid sample at each point,

Means the average thickness of the liquid sample,

Quot; means a transmission value,

Means a linear damping coefficient.

Since the calculated linear attenuation coefficient is a constant value, the absorbance at the reference thickness of the liquid sample is calculated as shown in [Equation 16] to [Equation 20].

는 스캔된 이미지로부터 얻은 분석광의 강도를 의미하고,

는 액체시료의 기준두께를 의미하며,

는 액체시료의 현재두께를 의미하고,

는 기준두께에서 액체시료의 흡광도를 의미하며,

는 현재두께에서 액체시료의 흡광도를 의미한다.
here,

Means the intensity of the analysis light obtained from the scanned image,

Means the reference thickness of the liquid sample,

Means the current thickness of the liquid sample,

Means the absorbance of the liquid sample at the reference thickness,

Means the absorbance of the liquid sample at the present thickness.

After calculating the absorbance at the reference thickness through the above equation, the amount of the solute contained in the liquid sample 110 was calculated by applying the calculated absorbance to the relationship between the absorbance and the mass ratio.

10 is a flowchart for explaining a liquid sample analyzing method according to an embodiment of the present invention.

Referring to FIG. 10, the liquid sample analyzing method calculates the amount of the solute contained in the liquid sample 110 by using a small amount of the liquid sample 110.

In the first step, a liquid sample is placed (S100). In the first step, the liquid sample 110 is disposed on the upper surface of the lower transparent glass 130. At this time, the liquid sample 110 is small and may be in the form of a drop.

In the second step, the height of the upper transparent glass is adjusted (S110). In the second step, the upper transparent glass 120 is adjusted to a predetermined height. The height of the upper transparent glass 120 is adjusted according to the rotation of the rotary protrusion 210. Here, the predetermined height is a height at which the liquid sample 110 and the upper transparent glass 120 are at least in contact with each other. That is, the gap between the upper transparent glass 120 and the lower transparent glass 130 is the thickness of the liquid sample 110.

At this time, the liquid sample 110 is pulled by itself due to the cohesive force generated in contact with the upper transparent glass 120, thereby spreading to the side.

In the third step, the liquid sample is irradiated with light (S120). The third step irradiates the liquid sample 110 with light emitted from the light source 140. The light source 140 irradiates a predetermined light.

In the fourth step, the absorbance is measured (S130). In the fourth step, the absorbance of the liquid sample 110 irradiated in the third step is measured by the two-dimensional optical analyzer 150. The two-dimensional optical analyzer 150 is a planar light transmission analyzer.

The fifth step calculates the volume, density, and amount of solute (S140). In the fifth step, the control unit 160 calculates the volume, density, and amount of the solute of the liquid sample 110 based on the absorbance measured in the fourth step.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be taken by way of limitation in the embodiment in which said invention is directed. It will be understood by those skilled in the art that various changes in form and detail may be made therein without departing from the scope of the appended claims.

1: Liquid sample analyzer
110: liquid sample
120: upper transparent glass
130: Lower transparent glass
140: Light source
150: Two-dimensional optical analyzer
160:
210: rotation projection
220: Support
221: Angle scale
222: first glass base jaw
223: second glass base jaw
224: third glass base jaw
225: fourth glass base jaw
226: Tweezers Home
310: first support portion
315: male screw
320: second support portion
325: Female threads

Claims (11)

A lower transparent glass in which a liquid sample is disposed on an upper surface;
An upper transparent glass for spreading the disposed liquid sample laterally;
A rotation protrusion for adjusting a height of the upper transparent glass to maintain a thickness of the liquid sample at a predetermined thickness;
A support portion supporting the lower transparent glass and the upper transparent glass including the rotation protrusions;
A light source for irradiating the liquid sample with light;
A two-dimensional optical analyzer for measuring an optical density of the irradiated liquid sample; And
And a controller for calculating the amount of solute using a relational equation between a predetermined absorbance and a mass ratio on the basis of the measured absorbance, using a liquid sample analyzer using absorbance,
Disposing a liquid sample on the upper surface of the lower transparent glass;
Spreading the disposed liquid sample laterally with the upper transparent glass;
Maintaining the upper transparent glass at a predetermined height;
Scanning the liquid sample to measure an area;
Measuring the optical density by irradiating the liquid sample with light; And
And calculating an amount of solute using a relational equation between a predetermined absorbance and a mass ratio based on the measured area and the absorbance.
The method according to claim 1,
Wherein the lower transparent glass and the upper transparent glass are kept parallel to each other.
The method according to claim 1,
The rotation protrusion
Wherein the height of the upper transparent glass is increased when the container is rotated clockwise and the height of the upper transparent glass is lowered when the container is rotated counterclockwise.
The method according to claim 1,
The support portion
A first supporter supporting the upper transparent glass and including a male screw; And
And a second support portion supporting the lower transparent glass and including a female screw.
5. The method of claim 4,
The rotation protrusion
Wherein the height of the upper transparent glass is adjusted in units of micrometers (탆) at 1/360 mm when the interval between the female screws is 1 mm.
5. The method of claim 4,
The first support portion
And the male screw is connected to the rotation protrusions and interlocked with each other.
The method according to claim 1,
Wherein,
Calculating a mass ratio (W / W fraction) based on the measured absorbance, and then calculating the amount of solute using the following equation:
[Mathematical Expression]

here,

Means the mass of the solute for the liquid sample,

Means the mass of the sample with respect to the liquid sample,

Means the mass ratio of the solute to the sample.
A lower transparent glass in which a liquid sample is disposed on an upper surface;
An upper transparent glass for pressing and spreading the disposed liquid sample to the side;
A rotation protrusion for adjusting the height of the upper transparent glass;
A support portion supporting the lower transparent glass and the upper transparent glass including the rotation protrusions; And
And a controller for calculating an absorbance at a reference thickness based on a predetermined reference thickness of the lower transparent glass and the upper transparent glass and calculating an amount of a solute for the liquid sample based on the calculated absorbance, Using a liquid sample analyzer,
Disposing a liquid sample on the upper surface of the lower transparent glass;
Spreading the disposed liquid sample laterally with the upper transparent glass;
Maintaining the upper transparent glass at a predetermined height;
Scanning the liquid sample to measure an area;
Measuring the optical density by irradiating the liquid sample with light; And
And calculating an amount of solute using a relational equation between a predetermined absorbance and a mass ratio based on the measured area and the absorbance.
9. The method of claim 8,
Wherein,
A method of analyzing a liquid sample using absorbance, characterized in that the absorbance at the reference thickness is calculated using the following equation:

Where OD _ref is the absorbance of the liquid sample at the reference thickness, t _ref is the reference thickness of the liquid sample, t _meas is the current thickness of the liquid sample, OD _meas is the absorbance of the liquid sample currently measured .
9. The method of claim 8,
Wherein,
And calculating the amount of solute in the liquid sample using the relational expression of the calculated absorbance and the mass ratio of the predetermined absorbance.
The method according to claim 1 or 8,
A method of analyzing a liquid sample using absorbance, characterized by calculating the density of a liquid sample using the area of the liquid sample and the following equation:

here,

Means the density of the liquid sample,

Means the mass of the liquid sample,

Means the volume of the liquid sample,

Means the area of the liquid sample,

Means the average thickness of the liquid sample.

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