KR102464351B1 - System for measuring residual chlorine concentration of ballast water - Google Patents

Abstract

The present invention relates to a system for measuring residual chlorine concentration in ballast water, which generates an electrical signal according to a chemical reaction of an oxidizing agent and generates a current proportional to the concentration of the oxidizing agent to measure a first residual chlorine concentration in ballast water. oxide sensor; DPD (N, N-Diethyl-p-Phenylenediamine) colorimetric residual oxide sensor for measuring the second residual chlorine concentration of ballast water using the injected buffer solution or reagent; and a controller for receiving, reading, and storing the first residual chlorine concentration signal and the second residual chlorine concentration signal.

Description

Ballast water residual chlorine concentration measurement system { SYSTEM FOR MEASURING RESIDUAL CHLORINE CONCENTRATION OF BALLAST WATER}

The present invention relates to a system for measuring residual chlorine concentration in ballast water, and more particularly, to a system for measuring residual chlorine concentration in ballast water used to maintain the balance of a ship.

Matters described in this background art section are prepared to enhance understanding of the background of the invention, and may include matters other than those of the prior art already known to those skilled in the art.

Residual oxide (Total Residual Oxidant, TRO) is an important factor that can guarantee treatment performance in a device that treats ballast water by an electrochemical method. Measuring and controlling TRO is an essential technology for the smooth operation of a ballast treatment system. Generally, chlorine, an oxidizing agent, is total chlorine and can be classified into free chlorine and combined chlorine. Free Chlorine is free roaming chlorine, and Hypochlorite ion (OCl-) and Hypochlorous acid (HOCl) are included in Free Chlorine. Combined chlorine has the role of an oxidizing agent, but in the form of an oxidizing agent combined with another form, such as an amine.

The two most common methods used for chlorine analysis are colorimetric and amperometry.

In general, a DPD (N,N-Diethyl-p-Phenylenediamine) colorimetric residual oxide sensor is used to measure the concentration of total chlorine in a ballast water treatment system of a ship. At this time, the DPD colorimetric residual oxide sensor is used in the ship's ballast water treatment device and has the following characteristics.

First, the characteristics of the DPD colorimetric measurement method are as follows.

1) Not affected by pH, temperature and salinity.

2) Periodic calibration is not required.

3) It is difficult to control because continuous measurement is impossible and measurement blanks occur in the sensor of the DPD colorimetric measurement method.

An example of the prior art of a residual oxide sensor of a current measurement method rather than a DPD colorimetric measurement method is disclosed in International Publication No. WO 2015/046762 A1. The current measurement method has the advantage of being able to continuously measure the residual oxide concentration, but it may change according to pH, temperature, flow rate and pressure, so periodic calibration is required.

The characteristics of the current measurement method are as follows.

1) Continuous measurement is possible, so control is easy.

2) The measured value changes over time under the influence of pH and temperature.

3) Periodic calibration is required, and the reference value used at this time is required.

4) Because it measures free chlorine, it is difficult to use it as a main device.

By applying the two methods in combination to the ballast water treatment device, more efficient operation and control of the ballast water treatment device is possible.

International Patent Publication No. WO 2015-046762

In order to solve the above-mentioned problems of the prior art, the present invention increases the accuracy of measuring the concentration of the oxidizing agent contained in the ballast water after the electrochemical treatment process through a hybrid residual oxide sensor using the DPD colorimetric measurement method and the current measurement method at the same time An object of the present invention is to provide a ballast water residual chlorine concentration measuring system capable of increasing control reliability.

In addition, an object of the present invention is to provide a system for measuring residual chlorine concentration in ballast water, which can read the measured value of the DPD residual oxide sensor and use it as a reference value for calibration when using a residual oxide sensor of a current measurement method that requires periodic calibration. .

In addition, in the event of a measurement gap in the DPD residual oxide sensor due to a functional error of the residual oxide sensor of the DPD colorimetric measurement method or a severe fluctuation in the measured value, the residual oxide sensor of the current measurement method is used as redundancy to continuously measure the value. It is an object of the present invention to provide a ballast water residual chlorine concentration measuring system that can prevent measurement errors in advance by doing so.

A ballast water residual chlorine concentration measuring system according to an embodiment of the present invention includes a sampling pump for moving ballast water of a ship through pressure; A filter for filtering foreign substances in the ballast water pumped and moved by the sampling pump; A current measuring method residual oxide sensor for measuring a first residual chlorine concentration of ballast water that has passed through the filter by generating an electrical signal according to a chemical reaction of the oxidizing agent and generating a current proportional to the concentration of the oxidizing agent; A DPD (N,N-Diethyl-p-Phenylenediamine) colorimetric residual oxide sensor for measuring the second residual chlorine concentration of ballast water that has passed through the filter using the injected buffer solution or reagent; and a controller for receiving, reading, and storing the first residual chlorine concentration signal and the second residual chlorine concentration signal.

Here, the controller includes a signal transceiver for receiving a first residual chlorine concentration signal and a second residual chlorine concentration signal; and displaying the first residual chlorine concentration signal and the second residual chlorine concentration signal on the screen, and when the first residual chlorine concentration signal and the second residual chlorine concentration signal are within a set deviation, the first residual chlorine concentration signal and the second residual chlorine concentration signal A signal input/output sensor unit for storing the chlorine concentration signal is included.

In addition, the controller, when the first residual chlorine concentration signal and the second residual chlorine concentration signal are not within the set deviation, the signal input/output sensor unit generates an alarm and corrects the first residual chlorine concentration signal to the second residual chlorine concentration signal. .

In addition, when the controller calibrates the first residual chlorine concentration signal to the second residual chlorine concentration signal, it is calibrated using a setting conversion equation.

In addition, the DPD (N,N-Diethyl-p-Phenylenediamine) colorimetric residual oxide sensor is installed on the port side of the ship, and the current measurement method residual oxide sensor is installed on the starboard side of the ship.

According to the present invention, it is possible to increase control reliability by increasing the accuracy of measuring the oxidant concentration contained in ballast water after the electrochemical treatment process through the hybrid residual oxide sensor using the DPD colorimetry method and the current measurement method at the same time.

In addition, according to the present invention, when using a residual oxide sensor of a current measurement method that needs to be calibrated periodically, the measurement value of the DPD residual oxide sensor can be read and used as a reference value for calibration.

In addition, according to the present invention, when a measurement gap occurs in the DPD residual oxide sensor due to a functional error of the sensor or a severe fluctuation in the measured value in the residual oxide sensor of the DPD colorimetric measurement method, the residual oxide sensor of the current measurement method is used as redundancy. Measurement errors can be prevented in advance by continuously measuring values using

1 is a schematic diagram of a ship equipped with a system for measuring residual chlorine concentration in ballast water according to an embodiment of the present invention.
FIG. 2 is a configuration diagram of the residual oxide sensor of FIG. 1 .
FIG. 3 is a schematic diagram showing a state in which the DPD colorimetric residual oxide sensor of FIG. 1 is disposed.
4 is a block diagram of a controller according to an embodiment of the present invention.
5 is a schematic diagram of a ship equipped with a system for measuring residual chlorine concentration in ballast water according to an embodiment of the present invention.
6 is a flow chart showing a process for measuring residual chlorine concentration in ballast water according to an embodiment of the present invention.

Advantages and features of the present invention, and methods of achieving them, will become clear with reference to the embodiments described below in conjunction with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below and may be implemented in a variety of different forms. Only the examples are provided to make the disclosure of the present invention complete, and to fully inform those skilled in the art of the scope of the invention to which the present invention belongs, and the present invention will be defined by the scope of the claims. only

1 is a schematic diagram of a ballast water residual chlorine concentration measurement system provided to a ship according to an embodiment of the present invention.

Referring to FIG. 1, the ballast water residual chlorine concentration measuring system 1000 provided in the ship includes a sampling pump 100, a filter 200, and a total residual oxide sensor 300 ), a DPD (N,N-Diethyl-p-Phenylenediamine) colorimetric measurement method, and a residual oxide sensor 400 and a controller 500.

First, the overall structure of the ballast water residual chlorine concentration measuring system will be described. A filter 200 is provided at the outlet of the sampling pump 100, and a current measurement method residual oxide sensor 300 and a DPD (N,N and kDiethyl-p-Phenylenediamine) colorimetric measurement method are used in the tube to which the filter 200 is connected. A residual oxide sensor 400 is provided. In addition, the controller 500 is provided to control the residual oxide sensor 300 of the current measurement method and the residual oxide sensor 400 of the DPD (N, N and kDiethyl-p-Phenylenediamine) colorimetric measurement method.

In addition, the filter 200 is connected to the ballast tank 20 through a pipe, a pipe to which the inlet and outlet of the sampling pump 100 are connected, a pipe to which the filter 200 and the current measurement residual oxide sensor 300 are connected Flow control valves 11, 12, 13, and 14 are connected between the tubes to which the residual oxide sensor 300 of the current measurement method and the residual oxide sensor 400 of the DPD colorimetric measurement method are connected. In this case, the residual oxide sensor 300 of the current measurement method and the residual oxide sensor 400 of the DPD colorimetric measurement method may be connected in a series structure. In addition, the residual oxide sensor 300 of the current measurement method and the residual oxide sensor 400 of the DPD colorimetric measurement method are located in pipes that are branched in parallel from the pipe connecting the filter 200 and the ballast tank 20, respectively, and have a parallel structure can also be connected to

Here, another device may be further provided between the pipe to which the residual oxide sensor 300 of the current measurement method and the residual oxide sensor 400 of the DPD colorimetry method are connected (see FIG. 3 ). Also, ballast water is drained from the pipe to which the residual oxide sensor 300 of the current measurement method and the residual oxide sensor 400 of the DPD colorimetry method are connected.

Then, each component of the ballast water residual chlorine concentration measuring system will be described in detail.

The sampling pump 100 moves the ship's ballast water (or ballast water) through pressure. The sampling pump 100 allows the sampled ballast water to be smoothly supplied to the residual oxide sensor 300 of the current measurement method and the residual oxide sensor 400 of the DPD colorimetric measurement method.

The filter 200 is installed in a pipe to which the outlet of the sampling pump 100 is connected, and filters foreign substances in the ballast water pumped and moved by the sampling pump 100 . At this time, the filter 200 minimizes foreign matter particles included in the sampled ballast water, thereby increasing the accuracy of the measured values measured by the residual oxide sensor 300 of the current measurement method and the residual oxide sensor 400 of the DPD colorimetric measurement method. can

The current measurement method residual oxide sensor 300 generates an electrical signal according to the chemical reaction of the oxidizing agent and generates a current proportional to the concentration of the oxidizing agent to measure the first residual chlorine concentration of the ballast water passing through the filter. Here, the current measuring method residual oxide sensor 300 measures the first residual chlorine concentration as the intensity of the current.

That is, the current measurement method is an electrochemical measurement method in which a signal is output by measuring a potential difference generated by an electrochemical reaction at an interface between an electrode and an internal electrolyte.

The residual oxide sensor 300 of the current measurement method may be configured so that the sampled ballast water continuously flows through the pipe.

The DPD colorimetric residual oxide sensor 400 measures the second residual chlorine concentration of the ballast water passing through the filter using the injected buffer solution or reagent.

In one embodiment of the present invention, in order to classify the residual chlorine concentrations measured by the residual oxide sensor 300 of the current measurement method and the residual oxide sensor 400 of the DPD colorimetric measurement method, the first residual chlorine concentration and the second residual chlorine concentration are respectively measured. It was marked separately.

A hybrid residual oxide sensor is a sensor that refers to a residual oxide sensor 300 of a current measurement method and a residual oxide sensor 400 of a DPD colorimetric measurement method, and such a hybrid residual oxide sensor is used in an embodiment of the present invention. .

The DPD colorimetric method is based on the DPD reaction with active halogens. This measurement method is a standard method for the analysis of residual chlorine and other chlorine oxidants, and uses a DPD reagent to form a colored material.

The controller 500 receives, reads, and stores the first residual chlorine concentration signal and the second residual chlorine concentration signal. In one embodiment of the present invention, in order to distinguish the signals received from the residual oxide sensor 300 of the current measurement method and the residual oxide sensor 400 of the DPD colorimetric measurement method, the first residual chlorine concentration signal and the second residual chlorine concentration signal, respectively, It was marked separately.

Here, the controller 500 displays the signal transceiver 510 for receiving the first residual chlorine concentration signal and the second residual chlorine concentration signal and the first residual chlorine concentration signal and the second residual chlorine concentration signal on a screen, and a signal input/output sensor unit 520 for storing the first residual chlorine concentration signal and the second residual chlorine concentration signal when the first residual chlorine concentration signal and the second residual chlorine concentration signal are within a set deviation.

In addition, the controller 500, when the first residual chlorine concentration signal and the second residual chlorine concentration signal are not within the set deviation, the signal input/output sensor unit generates an alarm and converts the first residual chlorine concentration signal into the second residual chlorine concentration signal. corrected with

In addition, when the controller 500 calibrates the first residual chlorine concentration signal into the second residual chlorine concentration signal, the calibration is performed using a setting conversion equation. Here, the setting conversion equation is a conversion equation that can be set by the user through a sufficiently large number of repeated experiments.

In addition, the DPD (N,N-Diethyl-p-Phenylenediamine) colorimetric residual oxide sensor 400 is installed on the port side of the ship, and the current measurement residual oxide sensor 300 is installed on the starboard side of the ship. installed on the side.

FIG. 2 is a configuration diagram of the residual oxide sensor of FIG. 1 .

Referring to FIG. 2 , the current measurement type residual oxide sensor 300 includes two electrodes, an anode 340 and a cathode 350 . The anode 340 may be divided into a reference electrode 342 and a counter electrode 341 enabling stable measurement.

An electrode shaft 330 is connected to the anode 34 . An amplifier is installed inside the electrode shaft 330, and a cover 310 is placed on the pole terminal of the electrode shaft 330.

The cathode 350 is a working electrode that causes an oxidation or reduction reaction of an analyte. Here, an example of the reaction of the working electrode can be expressed as Scheme 1.

[Scheme 1]

Cl ₂ + 2e- → 2Cl ^-

The cathode 350 is covered by a membrane cap on the membrane.

FIG. 3 is a schematic diagram showing a state in which the DPD colorimetric residual oxide sensor of FIG. 1 is disposed.

Referring to FIG. 3 , the DPD colorimetric residual oxide sensor 400 receives a reagent and measures the second residual chlorine concentration of the ballast water. At this time, the DPD colorimetric residual oxide sensor 400 receives the reagent pumped by the pump 120 through pressure. The measured second residual chlorine concentration signal is transmitted to the controller 500. A buffer solution may be injected into the DPD colorimetric residual oxide sensor 400 instead of a reagent.

On one side of the DPD colorimetric measurement method residual oxide sensor 400, a pump 110, a regulator 30, a sol valve 40, and a check valve 50 are sequentially disposed, and the pump 110 ) Flow control valves 15 and 16 are disposed on the pipes connected to the inlet and outlet sides of the

The DPD colorimetric residual oxide sensor 400 has a principle of measuring the residual chlorine concentration by using a buffer solution or a reagent to form a color-colored material based on the reaction between chlorine and DPD. Specifically, the DPD colorimetric residual oxide sensor 400 measures absorbance by absorbing light transmitted through a sample using a light source, and measures the concentration of the solution through a correlation between the absorbance and the concentration of the buffer solution. . In the DPD colorimetry method residual oxide sensor 400, the color-changed sampling ballast water is drained.

4 is a block diagram of a controller according to an embodiment of the present invention.

Referring to FIG. 4 , the controller 500 may include a signal transmission/reception unit 510 and a signal input/output sensor unit 520 .

The signal transceiver 510 receives a first residual chlorine concentration signal and a second residual chlorine concentration signal. The first residual chlorine concentration signal and the second residual chlorine concentration signal have a range of 4 to 20 mA.

The signal input/output sensor unit 520 displays the first residual chlorine concentration signal and the second residual chlorine concentration signal on the screen. Further, the signal input/output sensor unit 520 stores the first residual chlorine concentration signal and the second residual chlorine concentration signal when the first residual chlorine concentration signal and the second residual chlorine concentration signal are within a set deviation.

Also, the signal input/output sensor unit 520 may display the first residual chlorine concentration signal and the second residual chlorine concentration signal on the screen in a text mode or the like.

In addition, the signal input/output sensor unit 520 is compatible with multiple communication protocols such as an RS communication function, and can control and monitor various equipment using the Modbus protocol.

5 is a schematic diagram of a ship equipped with a system for measuring residual chlorine concentration in ballast water according to an embodiment of the present invention.

Referring to FIG. 5 , the vessel 70 is provided with a residual oxide sensor 300 of a current measurement method and a residual oxide sensor 400 of a DPD colorimetric measurement method.

The pumps 130 and 140 are respectively connected to the residual oxide sensor 300 of the current measurement method and the residual oxide sensor 400 of the DPD colorimetric measurement method through a pipe, and the first residual chlorine concentration signal and the second residual chlorine concentration signal from the controller 500 are connected. Receive residual chlorine concentration signal.

In one embodiment of the present invention, the DPD colorimetric residual oxide sensor 400 is installed on the port side of the ship 70, and the current measurement method residual oxide sensor 300 is implemented to be installed on the starboard side of the ship 70, The residual oxide sensor 300 of the current measurement method may be installed on the port side of the ship 70, and the residual oxide sensor 400 of the DPD colorimetric measurement method may be installed on the starboard side of the ship 70. In addition, the residual oxide sensor 300 of the current measurement method and the residual oxide sensor 400 of the DPD colorimetric measurement method may be installed on the port or starboard side of the ship.

6 is a flow chart showing a process for measuring residual chlorine concentration in ballast water according to an embodiment of the present invention.

Referring to FIG. 6 , the ballast water residual chlorine concentration measurement process may include S100 to S400.

First, the residual oxide sensor 300 of the current measurement method and the residual oxide sensor 400 of the DPD colorimetric measurement method are operated (S100).

After S100, the output value of the residual oxide sensor 300 of the current measurement method and the output value of the residual oxide sensor 400 of the DPD colorimetric measurement method are collected in the signal transceiver 510 (S200).

After S200, the signal input/output sensor unit 520 determines whether the deviation between the output value of the residual oxide sensor 300 of the current measurement method and the output value of the residual oxide sensor 400 of the DPD colorimetric measurement method is within 10% (S300). In one embodiment of the present invention, 10% is set as an example of the set deviation, but is not limited thereto.

In S300, when the deviation between the output value of the residual oxide sensor 300 of the current measurement method and the output value of the residual oxide sensor 400 of the DPD colorimetric measurement method in the signal input/output sensor unit 520 is within 10%, the signal input/output sensor unit 520 ), the output value of the residual oxide sensor 300 of the current measurement method and the output value of the residual oxide sensor 400 of the DPD colorimetric measurement method are measured as the residual chlorine concentration (S400).

However, in S300, when the deviation between the output value of the residual oxide sensor 300 of the current measurement method and the output value of the residual oxide sensor 400 of the DPD colorimetry method in the signal input/output sensor unit 520 is not within 10%, the signal input/output sensor The unit 520 displays an alarm (S310) and corrects the output value of the current measurement method to the output value of the DPD method using the setting conversion formula (S320). Here, the setting conversion equation is a conversion equation that can be set by the user through a sufficiently large number of repeated experiments.

The above-described embodiments of the present invention have been described with reference to the embodiments shown in the drawings to aid understanding, but this is only exemplary, and various modifications and other equivalent embodiments may be made by those skilled in the art You will understand that it is possible. Therefore, the true technical protection scope of the present invention will be defined by the appended claims.

100: sampling pump 200: filter
300: current measurement residual oxide sensor
400: DPD colorimetric residual oxide sensor
500: controller 510: signal transmission and reception unit
520: signal input/output sensor unit

Claims (8)

A current measuring type residual oxide sensor measuring a first residual chlorine concentration of ballast water by generating an electrical signal according to a chemical reaction of an oxidizing agent and generating a current proportional to the concentration of the oxidizing agent;
DPD (N, N-Diethyl-p-Phenylenediamine) colorimetric residual oxide sensor for measuring the second residual chlorine concentration of ballast water using the injected buffer solution or reagent; and
A controller for receiving, reading, and storing the first residual chlorine concentration signal and the second residual chlorine concentration signal,
The controller may display a signal transceiver receiving the first residual chlorine concentration signal and the second residual chlorine concentration signal and the first residual chlorine concentration signal and the second residual chlorine concentration signal on a screen, and displaying the first residual chlorine concentration signal and the second residual chlorine concentration signal on a screen. A signal input/output sensor unit for storing the first residual chlorine concentration signal and the second residual chlorine concentration signal when the residual chlorine concentration signal and the second residual chlorine concentration signal are within a set deviation,
The controller, when the first residual chlorine concentration signal and the second residual chlorine concentration signal are not within the set deviation, the signal input/output sensor unit generates an alarm and converts the first residual chlorine concentration signal to the second residual chlorine concentration signal. Calibrate with the concentration signal,
The controller, when calibrating the first residual chlorine concentration signal with the second residual chlorine concentration signal, corrects using a setting conversion equation,
Ballast water residual chlorine concentration, characterized in that the DPD (N, N-Diethyl-p-Phenylenediamine) colorimetric residual oxide sensor is installed on the port side of the ship, and the current measurement residual oxide sensor is installed on the starboard side of the ship. measurement system. According to claim 1,
The ballast water residual chlorine concentration measuring system, characterized in that the current measurement method residual oxide sensor and the DPD (N, N-Diethyl-p-Phenylenediamine) colorimetric residual oxide sensor are connected in series. According to claim 1,
The ballast water residual chlorine concentration measuring system, characterized in that the current measuring method residual oxide sensor and the DPD (N, N-Diethyl-p-Phenylenediamine) colorimetric residual oxide sensor are connected in parallel. According to claim 1,
Sampling pumps that move the vessel's ballast water through pressure; and
Ballast water residual chlorine concentration measuring system further comprising a filter for filtering foreign substances in the ballast water pumped and moved by the sampling pump. delete delete delete delete

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