KR102021938B1 - Method for measuring of total residual oxidant having light-source calibrating function - Google Patents

Abstract

The present invention comprises the steps of operating the light source by applying a current to the light source; Determining whether the intensity of light emitted from the light source is a reference value; When the intensity of light emitted from the light source is not the reference value, the current value applied to the light source is adjusted to reach the reference value, and when the intensity of light emitted from the light source reaches the reference value, the sample is introduced into the measuring cell. Making a step; Measuring a zero point value after irradiating light of a predetermined wavelength to pass through the measurement cell from the light source to reach the light receiving unit; Discharging the sample whose zero value is measured from the measuring cell and introducing a new sample into the measuring cell; Injecting a coloring reagent into the measuring cell, passing the measuring cell from the light source to reach the light receiving unit at a predetermined wavelength, and measuring a span value; Calculating residual chlorine concentration by converting the difference between the measured zero point value and the span value into a TRO concentration value; And it relates to a residual chlorine concentration measuring method having a light source correction function comprising the step of discharging the sample from which the span value is measured from the measuring cell.

Description

{Method for measuring of total residual oxidant having light-source calibrating function}

The present invention relates to a method for measuring residual chlorine concentration using a DPD colorimetric method, and more particularly, to a method for measuring residual chlorine concentration having a light source correction function.

Generally, cargo ships transported by sea are mostly one-way except for ships reciprocating to exchange similar cargoes. In addition, after returning to the full sail after the one-way operation, the ballast water (ballast water) is introduced into the ship and sailed in the ballast state for improving the balance, safety, and steering performance of the ship.

At this time, the ballast water is filled in one port through a ballasting operation and transferred to another, and discharged in a new port through a deballasting operation. As such, the release of marine organisms and pathogens contained in ballast water carried from remote locations is not only harmful to the new environment, but can also be dangerous to both humans and animals in new ports.

Introducing non-natural marine life into new ecosystems can have destructive effects on natural flora and fauna that may not have natural defenses against new species. In addition, harmful bacterial pathogens such as cholera may be present in the original ports. These pathogens can multiply in the ballast tanks over time, causing disease in the areas where they are released.

In the United States, where 65% of the world's ships call in recent years, the US Maritime Organization (IMO) requires ballast water treatment technology that is 1,000 times stronger than that agreed by the International Maritime Organization (IMO) and established its own USCG Phase. It is showing its movement to protect the marine environment.

To eliminate the risk posed by these marine organisms and pathogens, a ballast water treatment apparatus is used in which the ballast water is electrolyzed or a chemical is injected into the ballast tank to sterilize the ballast water.

Here, in the case of sterilizing the ballast water by electrolyzing the ballast water or injecting chemicals into the ballast water, whether the ballast water treatment apparatus operates normally to discharge the ballast water, that is, whether the ballast water is processed to meet the criteria of the IMO. You need to check.

The conventional method for inspecting a ballast water treatment apparatus is a method for determining whether the number of ballasts discharged meets the standard value of IMO by measuring the concentration of residual oxide (TRO) of the ballast water discharged. In this method, TRO concentration was generally measured by DPD (N, N-Diethyl-p-Phenylenediamine) method. The DPD method is a method of measuring the TRO concentration by mixing a DPD reagent with a sample collected and comparing the color of the mixture with a color table (a table showing chlorine levels according to color gradation).

Specifically, the principle of measuring TRO concentration using the DPD colorimetric method is a method of measuring the intensity of a specific wavelength of light passing through a sample and converting it into a TRO value using the absorbance difference. At this time, LED is generally used as a light source to generate light passing through the sample. By the way, the LED used for measuring the TRO concentration is produced in a large amount in a semiconductor factory, but even if the LED is manufactured in the same manufacturing environment, the light intensity will vary little by little. Therefore, due to the characteristics of the LED in mass production of the residual chlorine measuring instrument, the intensity of light is changed at the time of measuring the TRO concentration, so even if the TRO is measured by the same measuring method, it is inevitable that an error occurs for each equipment.

Prior Art Document 1: Registered Patent No. 10-1108561 (January 30, 2012)

Prior Art Document 2: Registered Patent No. 10-1395637 (2014.05.16. Notification)

An object of the present invention is to provide a method for measuring residual chlorine concentration having a light source correction function capable of accurately measuring residual chlorine concentration even when LEDs having different characteristics are used as light sources.

In order to achieve the above object, the residual chlorine concentration measuring method having a light source correction function according to the present invention comprises the steps of operating a light source by applying a current to the light source; Determining whether the intensity of light emitted from the light source is a reference value; When the intensity of light emitted from the light source is not the reference value, the current value applied to the light source is adjusted to reach the reference value, and when the intensity of light emitted from the light source reaches the reference value, the sample is introduced into the measuring cell. Making a step; Measuring a zero point value after irradiating light of a predetermined wavelength to pass through the measurement cell from the light source to reach the light receiving unit; Discharging the sample whose zero value is measured from the measuring cell and introducing a new sample into the measuring cell; Injecting a coloring reagent into the measuring cell, passing the measuring cell from the light source to reach the light receiving unit at a predetermined wavelength, and measuring a span value; Calculating residual chlorine concentration by converting the difference between the measured zero point value and the span value into a TRO concentration value; And discharging the sample whose span value is measured from the measuring cell.

Preferably, the light source is an LED for irradiating white light, the light receiving unit is characterized in that the RGB sensor.

More preferably, in the step of measuring the zero point value, the light source is irradiated with light of the blue wavelength and light of the green wavelength, the light receiving portion is a zero point value at the green wavelength and the zero point value at the blue wavelength In the measuring and measuring of the span value, the light source emits light of blue wavelength and light of green wavelength, and the light receiving unit measures a span value of green wavelength and a span value of blue wavelength. do.

Here, in the step of calculating the residual chlorine concentration, when the difference between the zero point value and the span value at the green wavelength exceeds 10 mg / L, the difference between the zero point value and the span value at the blue wavelength is converted into TRO concentration. When the difference between the zero point value and the span value at the green wavelength is 10 mg / L or less, the difference between the zero point value and the span value at the green wavelength is converted into the TRO concentration.

Preferably, the method further comprises the step of washing the inside of the measuring cell using the washing water before introducing the sample to be measured into the measuring cell.

According to the present invention, even when measuring TRO concentration using LEDs having different characteristics, precise TRO concentration measurement is possible by correcting the intensity of the light source so that the light intensity of the LED light source is kept constant.

In addition, according to the present invention, when measuring a high concentration of the sample, since the TRO concentration is calculated using the light of the blue wavelength in which the frequency gradient according to the absorbance is large, the high concentration of the sample can be accurately measured.

1 is a view schematically showing the configuration of a residual chlorine concentration measuring apparatus having a light source correction function according to the present invention,
2 is a flowchart schematically showing a method for measuring residual chlorine concentration having a light source correction function according to the present invention;
3 is a flowchart schematically illustrating a method for measuring residual chlorine concentration having a light source correction function according to another embodiment of the present invention;
4 is a graph showing measurement slopes of green and blue wavelengths at high concentrations of TRO.

Hereinafter, with reference to the accompanying drawings will be described a preferred embodiment of the residual chlorine concentration measuring method having a light source correction function according to the present invention. For reference, in the following description of the present invention, terms referring to the components of the present invention are named in consideration of the function of each component, and should not be understood as a meaning of limiting the technical components of the present invention. Will be.

Residual chlorine concentration measuring method having a light source correction function according to the present invention is to accurately measure a high concentration of the sample, it is performed using the residual chlorine measuring apparatus shown in FIG.

First, referring to FIG. 1, a residual chlorine concentration measuring apparatus includes a measurement target sample, for example, a measurement cell 100 into which ballast water flows in and out, a light source 200 provided at one side of the measurement cell 100, and a measurement cell The light receiving unit 300 provided on the other side of the 100, and the light source 200 and the control unit 400 connected to the light receiving unit 300 is included.

The measuring cell 100 has an inlet on one side and an outlet on the other side so that the sample to be measured can be introduced and discharged. The measuring cell 100 is made of a transparent material so that the light irradiated from the light source 200 can reach the light receiving unit 300 through a sample inside the measuring cell 100. In addition, the measurement cell 100 may be provided with, for example, mixing means so that the sample is accommodated therein, and the contained sample is evenly mixed.

The light source 200 may be a white LED emitting white light. Here, the light source 200 may be configured to irradiate light of the green wavelength of 510 ~ 515nm and light of the blue wavelength of 460 ~ 480nm. In addition, the light receiving unit 300 is preferably an RGB sensor capable of absorbing light of red, green, and blue wavelengths to measure absorbance. The control unit 400 controls the wavelength irradiated from the light source 200 and converts the TRO concentration based on the absorbance measured by the light receiving unit 300.

With reference to Figure 2, the method for measuring the residual chlorine concentration according to the present invention.

First, by applying a current of a predetermined value to the LED light source 200 to operate the LED light source 200 to irradiate light from the LED light source 200 (S100). Then, the light irradiated from the LED light source 200 passes through the measuring cell 100 and is transmitted to the light receiving unit 300, that is, the RGB sensor.

Then, the controller 400 measures the intensity of the light received by the RGB sensor 300. At this time, the controller 400 determines whether the intensity of the light emitted from the LED light source 200 is a reference value (S200).

Subsequently, the controller 400 corrects the light intensity of the LED light source 200 according to the intensity of the light received by the RGB sensor 300, that is, the light emitted from the LED light source 200. In detail, when the intensity of light emitted from the LED light source 200 is not the reference value, the controller 400 adjusts the current value applied to the LED light source 200 to reach the reference intensity (S310). In addition, when the intensity of the light irradiated from the LED light source 200 reaches the reference value, the control unit 400 cleans the measuring cell 100 by introducing the washing water into the measuring cell 100 and then discharging it (S320). It is preferable that the cleaning of the measurement cell 100 is always performed before the sample introduction steps described later.

Next, the sample to be measured, for example, ballast water is introduced into the measuring cell 100 through the inlet of the measuring cell 100 (S400).

In addition, after irradiating the light from the light source 200 to allow the irradiated light to pass through the measuring cell 100 to reach the RGB sensor 300, a zero point value for the sample is measured (S500). In this zero point measurement step, the control unit 400 controls the light source 200 to irradiate light of a predetermined wavelength, and the light receiving unit 300 passes through a sample of the measurement cell 100 from the light source 200. Absorb light at 300) and measure absorbance. Then, the control unit 400 compares the absorbance of the light receiving unit 300 with the calibration curve and measures the zero point value of the TRO concentration, that is, the reference value.

When the zero point value of the TRO concentration of the sample is measured, the sample which has been measured is discharged through the outlet of the measuring cell 100 (S610), and a new sample to be measured is introduced again into the measuring cell 100 (S620). . Of course, before the new measurement target sample is introduced into the measurement cell 100, the inside of the measurement cell 100 may be washed by introducing and discharging the washing water into the measurement cell 100.

Subsequently, a color developing reagent is added to the measuring cell 100 (S700). Then, after irradiating the light from the light source 200 to pass through the measuring cell 100 to reach the light receiving unit 300, the span value for the sample is measured (S800). In this span value measurement step, the control unit 400 controls the light source 200 to irradiate light having a predetermined wavelength, and the light receiving unit 300 passes through the sample of the measurement cell 100 from the light source 200 and receives the light receiving unit 300. Absorb the light that reaches a) and measure the absorbance. Then, the control unit 400 compares the absorbance of the light receiving unit 300 with the calibration curve and measures the span value of the TRO concentration.

Subsequently, the controller 400 calculates the TRO concentration by using the measured difference between the zero point value and the span value (S900). When the span value of the TRO concentration for the sample is measured, the control unit 400 calculates the residual chlorine concentration by converting the difference between the measured zero point value and the span value into the TRO concentration value.

Finally, when the concentration measurement of the sample is completed, the sample whose span value is measured is discharged from the measurement cell 100 (S1000).

As described above, the method for measuring residual chlorine having a light source correction function according to the present invention maintains the intensity of the light source so that the light intensity of the LED light source 200 is maintained even when the TRO concentration is measured using LEDs having different characteristics. Precise TRO concentration measurement is possible by calibration.

Meanwhile, FIG. 3 is a flowchart schematically illustrating a method for measuring residual chlorine having a light source correction function according to another embodiment of the present invention. In the aforementioned zero point value measuring step S500, the controller 400 After controlling the light source to irradiate light of green wavelengths (510 to 515 nm) from the light source 200, the light source may be controlled to irradiate light of the blue wavelengths (460 to 480 nm) from the light source 200 again. The light receiving unit 300 measures a zero point value at a green wavelength and a zero point value at a blue wavelength of light emitted from the light source 200, respectively.

In addition, in the measuring the above-described span value (S800), the control unit 400 controls the light source so that light of green wavelengths (510 to 515 nm) is irradiated from the light source 200, and then again the blue wavelength from the light source 200. The light source is controlled so that light of (460 to 480 nm) is irradiated. The light receiving unit 300 measures the span value at the green wavelength and the blue value at the blue wavelength of the light emitted from the light source 200, respectively.

And, in step S900 of calculating the TRO concentration using the difference between the zero point value and the span value, the controller 400 determines that the difference between the zero point value and the span value measured at the green wavelength exceeds 10 mg / L. In this case, the difference between the zero point value and the span value measured at the blue wavelength is converted into the TRO concentration (S910). On the other hand, when the difference between the zero point value and the span value measured at the green wavelength is 10 mg / L or less, the controller 400 converts the difference between the zero point value and the span value measured at the green wavelength to the TRO concentration (S920). That is, when the difference between the zero point value and the span value measured at the green wavelength exceeds a predetermined value, the controller 400 determines that the measured sample has a high concentration, and uses the measured values at the blue wavelength with higher accuracy of the measurement. Calculate the TRO concentration.

As can be seen from the graph shown in FIG. 4, in the case of a sample having a high concentration of TRO concentration of, for example, 10 mg / L or more, the frequency separation width according to the difference in the measured value at the blue wavelength and the green wavelength is shown as blue. The slope of the wavelength is approximately two times greater than the slope of the green wavelength. This means that for high concentration samples, it is more accurate to measure the concentration using the blue wavelength.

As described above, in the method of measuring residual chlorine concentration having a light source correction function according to the present invention, when measuring a high concentration of the sample, since the TRO concentration is calculated using light having a blue wavelength in which the frequency gradient according to the absorbance is large, the high concentration of the sample is measured. Accurate measurement is also possible.

The embodiments of the present invention described above are merely illustrative of the technical idea of the present invention, and the protection scope of the present invention should be interpreted by the following claims. In addition, one of ordinary skill in the art to which the present invention pertains will be capable of various modifications and variations without departing from the essential characteristics of the present invention, all technical ideas within the scope equivalent to the present invention of the present invention It should be interpreted as being included in the scope of rights.

Claims (5)

Operating a light source by applying a current to the light source;
Determining whether the intensity of light emitted from the light source is a reference value;
When the intensity of light emitted from the light source is not the reference value, the current value applied to the light source is adjusted to reach the reference value, and when the intensity of light emitted from the light source reaches the reference value, the sample is introduced into the measuring cell. Making a step;
Measuring a zero point value after irradiating light of a predetermined wavelength to pass through the measurement cell from the light source to reach the light receiving unit;
Discharging the sample whose zero value is measured from the measuring cell and introducing a new sample into the measuring cell;
Injecting a coloring reagent into the measuring cell, passing the measuring cell from the light source to reach the light receiving unit at a predetermined wavelength, and measuring a span value;
Calculating residual chlorine concentration by converting the difference between the measured zero point value and the span value into a TRO concentration value; And
And discharging the sample from which the span value is measured, from the measuring cell.
In the measuring of the zero point value, the light source emits light of a blue wavelength and light of a green wavelength, and the light receiving unit measures a zero point value of a green wavelength and a zero point value of a blue wavelength,
In the measuring of the span value, the light source irradiates light of a blue wavelength and light of a green wavelength, and the light receiving unit measures a span value of a green wavelength and a span value of a blue wavelength,
In the step of calculating the residual chlorine concentration, when the difference between the zero point value and the span value at the green wavelength exceeds 10 mg / L, the difference between the zero point value and the span value at the blue wavelength is converted into TRO concentration, When the difference between the zero point value and the span value at the green wavelength is 10 mg / L or less, the residual chlorine concentration measurement with the light source correction function is characterized by converting the difference between the zero point value and the span value at the green wavelength into TRO concentration. Way.
The method of claim 1,
Residual chlorine concentration measurement method having a light source correction function characterized in that it further comprises the step of washing the inside of the measuring cell using the washing water before the sample to be measured into the measuring cell. delete delete delete

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