KR101302734B1 - Tro sensor with quantity of flow and fluid pressure buffer chamber - Google Patents

Abstract

PURPOSE: A total residual oxide (TRO) concentration sensor with a fluid pressure and flow rate buffer is provided to prevent influences of a ballaster water pipe change on a sample collected by the TRO sensor of a vessel ballaster water processing device and to obtain the stable inflow and pressure of ballaster water. CONSTITUTION: A TRO concentration sensor with a fluid pressure and flow rate buffer includes a TRO sensor (20), a pump (30), and an atmospheric pressure buffer chamber (40). The TRO sensor forms a sample by supplying fluid flowing into a fluid inlet to a measurement unit cuvette via a solenoid valve and develops colors of the sample by supplying a buffer solution and a DPD color developing reagent. A measurement sensor of the TRO sensor measures the extent of the color development of the sample, thereby measuring the concentration of TRO. The pump is formed on an inlet pipe connected to the fluid inlet of the TRO sensor and supplies the fluid. The lower part of one side of the atmospheric pressure buffer chamber is connected to a sampling pipe (410) sampling the fluid from the chamber or a main pipe (10) in which the fluid is stored. The lower part of the other side of the atmospheric pressure buffer chamber is connected to an outflow pipe (420) connected to the pump so that the atmospheric pressure buffer chamber stores the collected fluid. An atmospheric pressure control pipe (400) connected to an external atmosphere is formed on the upper part of the atmospheric pressure buffer chamber and supplies the fluid sample to the pump at a fixed flow rate always under the atmospheric pressure.

Description

Total residual oxide concentration sensor with hydraulic flow buffer {TRO sensor with quantity of flow and fluid pressure buffer chamber}

The present invention transfers the liquid flowing into the liquid inlet end to the measuring unit cuvette through the solenoid valve to form a sample, and supply the buffer solution and DPD coloring reagent to the cuvette to color the sample, the measurement sensor is the A TRO sensor for measuring the amount of coloring to measure the total residual oxide concentration; A pump which is formed in an inlet pipe connected to the liquid inlet end of the TRO sensor and supplies liquid; At the bottom of one side, a sampling pipe for collecting liquid from the main pipe or chamber in which the liquid to be measured is stored is connected. At the bottom of the other side, an outflow pipe connected to the pump is connected to temporarily store the sampled liquid. An atmospheric pressure control tube is formed to communicate with the atmosphere is configured to the atmospheric pressure buffer chamber to supply the liquid sample at a constant flow rate at atmospheric pressure to the pump to remove the measurement error caused by the variation of the sample flow rate and pressure A total residual oxide concentration sensor having a flow buffer.

In general, ships are operating by introducing ballast water into a ballast tank provided in a ship in order to reduce the center of gravity of the ship due to loading and unloading of cargo and to enable safe navigation.

By the way, the ballast water filled in the ballast tank of the ship includes various marine life and pathogens, and the side effects of disturbing the environment and ecosystem as the marine life or pathogens in a specific area introduced into the ballast water flows to other waters. Will cause.

Therefore, in 2004, the International Maritime Organization established a treaty that strictly regulated the inflow and outflow of ballast water to clean and sterilize marine organisms and pathogens contained in the ballast water.

In order to purify and sterilize the ballast water, a method of generating sodium hypochlorite is generally used by passing seawater (ie, ballast water) flowing into an equilibrium tank through an electrolytic cell.

Prior Patent Registration Nos. 10-1122294 and 10-0948579 are techniques related to such electrolysis devices for treating ballast water, and interest in the development of such devices is still increasing.

The TRO (Total Residual Oxidant) sensor is a part of the ballast water treatment system using the electrolysis device as described above, and the TRO sensor device using the DPD color measurement method is used in the ballast mode of the ballast water treatment device. The production concentration of sodium chlorate and the neutralized concentration in the de-ballast mode are measured to control the current amount of the rectifier and the input amount of the neutralizing agent.

However, the TRO sensor is very sensitive to the flow rate and pressure of the sample flowing into the sensor in the TRO concentration measurement has the disadvantage that the measured value is irregularly shaken.

In detail, in the prior art method, the TRO sensor directly collects a liquid sample from the main pipe 10 to the pump 30 as shown in FIG. 2 to determine the TRO concentration by using the DPD Colorimetric Method. It is an on-line measuring device that measures in real time. The sample is collected through the built-in solenoid valve and flows into the measuring unit cuvette. The TRO concentration is measured by detecting the color change of the sample by supplying a certain amount of buffer solution and DPD coloring reagent.

In the ballast water treatment system, the measured value of the TRO sensor determines the amount of current required for electrolysis and the amount of neutralizer required for neutralization. Is very important.

However, the TRO sensor using the DPD color development method has a characteristic in which the amount of sample taken by the flow rate and pressure of the incoming liquid sample is sensitively reacted, so that even a small operation change and air inflow of the ballast water main pipe 10 are measured. The concentration value fluctuates.

The reason is that the measurement method applied to the TRO sensor as described above is a method of calculating the concentration value by measuring the degree of color development of the sample using the wavelength of light, as shown in Figure 3 of the sample introduced into the measuring cuvette If the amount is small, the color development becomes excessive and the measured value with high concentration is displayed. If the amount of the sample is too large, the measured value is lower as the concentration is diluted.

Therefore, in the ballast water treatment system, the sample liquid flowing into the TRO sensor must have a constant and stable inflow flow rate and pressure to accurately measure the concentration of the TRO sensor. The prior art TRO sensor is a ballast water main pipe ( As the measured concentration value is affected by the change of 10), it is difficult to transmit accurate and immediate information to the operation of the ballast water treatment system.

In order to solve the above problems, the present invention is to ensure that the sample collected by the TRO sensor in the ballast water treatment device is not affected by the change in the ballast water main pipe of the ship and has a constant and stable inflow flow rate and pressure, An object of the present invention is to provide a total residual oxide concentration sensor having a hydraulic flow buffer capable of measuring the concentration of a TRO sensor.

In order to solve the above problems, the present invention transfers the liquid flowing into the liquid inlet to the measuring unit cuvette through a solenoid valve to form a sample, and supplies the buffer solution and the DPD color reagent to the cuvette to color the sample. A TRO sensor for measuring a total amount of residual oxide by measuring a color development amount of the sample; A pump which is formed in an inlet pipe connected to the liquid inlet end of the TRO sensor and supplies liquid; At the bottom of one side, a sampling pipe for collecting liquid from the main pipe or chamber in which the liquid to be measured is stored is connected. At the bottom of the other side, an outflow pipe connected to the pump is connected to temporarily store the sampled liquid. An atmospheric pressure control tube is formed to communicate with the atmosphere is configured to the atmospheric pressure buffer chamber to supply the liquid sample at a constant flow rate at atmospheric pressure to the pump to remove the measurement error caused by the variation of the sample flow rate and pressure A total residual oxide concentration sensor with a flow buffer is a technical subject.

Here, the total residual oxide concentration sensor having the hydraulic flow buffer is used as the main pipe or chamber in which the main pipe of the ballast water treatment device is stored as the liquid to be measured, and the total residual oxide of the ballast water treatment device (TRO: Total Residual Oxidant). The concentration is preferably a TRO sensor having a hydraulic flow rate rectifying buffer, which can be constantly measured without errors due to sample flow rate and pressure fluctuation.

According to the present invention, the sample collected by the TRO sensor in the ballast water treatment apparatus is not affected by the change in the ballast water main pipe of the vessel and has a constant and stable inflow flow rate and pressure, thereby accurately measuring the concentration of the TRO sensor. It is an advantage that a total residual oxide concentration sensor with this possible hydraulic flow buffer is provided.

1 is a TRO sensor piping structure diagram of the present invention
Figure 2 is a structure diagram of the prior art TRO sensor piping
3 is an exemplary view illustrating a measurement method of a TRO sensor

Hereinafter, the present invention will be described with reference to the drawings. In the following description of the present invention, a detailed description of related arts or configurations will be omitted when it is determined that the gist of the present invention may be unnecessarily obscured will be.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory and are intended to be exemplary, self-explanatory, allowing for equivalent explanations of the present invention.

1 is a structure diagram of a TRO sensor piping according to the present invention, FIG. 2 is a structure diagram of a TRO sensor piping according to the related art, and FIG. 3 is an exemplary diagram illustrating a measurement method of a TRO sensor.

As shown in FIG. 1, the present invention includes a TRO sensor 20, a pump 30, a sampling pipe 410, an outlet pipe 420, an air pressure control pipe 400, and an atmospheric buffer chamber 40.

The Total Residual Oxidant (TRO) sensor of the present invention is an on-line measuring device that measures TRO concentration in real time using a DPD Colorimetric Method, and includes a solenoid valve containing a liquid flowing into a liquid inlet stage. The sample is transferred to the measuring unit cuvet to form a sample, and a certain amount of buffer solution and DPD coloring reagent are supplied to generate a color change according to the residual oxide concentration of the sample. Measure the concentration.

After the measurement, the sample is discharged using the discharge solenoid valve. After several cuvette cleaning processes, the next measurement is performed.

The ballast water treatment device treats ballast water by electrolyzing seawater to generate sodium hypochlorite (NaOCl) with strong sterilization power.In ballast mode, the concentration of sodium hypochlorite generated by electrolysis in the TRO sensor Measure the current to adjust the amount of current required for electrolysis.

In addition, in the de-ballast mode, which discharges ballast water, the concentration of sodium hypochlorite remaining in the ballast water must be neutralized and discharged according to the discharge allowance standard. In this case, the TRO sensor monitors the concentration of sodium hypochlorite in the neutralized treated water. It is used to measure and adjust the amount of neutralizer injected.

Pump 30 of the present invention is a device for supplying a liquid sample to be formed is formed in the inlet pipe connected to the liquid inlet end of the TRO sensor 20.

That is, the pump 30 is a device for taking a sample from the main pipe or chamber in which the liquid, which is the measurement target, is stored, and supply the sample to the TRO sensor 20.

In the related art method, since the pump 30 directly pumps a sample from the main pipe or the chamber in which the liquid, which is the object to be measured, is stored, and supplies it to the TRO sensor 20, a change in air pressure or flow rate occurs in the main pipe or the chamber. When bubbles were generated, the TRO sensor was immediately affected, causing an error in the measurement result.

In the present invention, in order to prevent this, the atmospheric pressure buffer chamber 40 is formed between the pump 30 and the main pipe or chamber in which the liquid to be measured is stored, so that the sample pumped up to the pump 30 is once the atmospheric buffer chamber. After being stored in 40 and stabilized, it is transferred to the TRO sensor 20.

The atmospheric buffer chamber 40 of the present invention is a chamber having a capacity for temporarily storing the liquid sampled by the pump 30 and is not limited to its shape. In addition, the sampling pipe 410 for collecting the liquid from the chamber is connected, and the other end of the outlet pipe 420 is connected to the pump 30 is connected.

In addition, an atmospheric pressure control tube 400 is formed at the top of the chamber to communicate with the external atmosphere so that the inside of the atmospheric buffer chamber 40 can always store a liquid sample in an atmospheric pressure atmosphere.

Therefore, the liquid sample temporarily stored in the atmospheric buffer chamber of the present invention is released in advance before the bubble contained therein into the TRO sensor 20, the liquid sample pushed to the abnormal pressure and flow rate is also the atmospheric buffer chamber. It is maintained in a stable state in the atmospheric pressure atmosphere of 40.

Therefore, according to the present invention, when supplying the liquid sample to be measured to the liquid inlet 200 of the TRO sensor 20 to the pump 30, the liquid sample can be supplied at a constant speed and flow rate at atmospheric pressure at all times. As a result, a quantitative sample may be contained in the internal cuvette of the TRO sensor 20 so that the correct TRO concentration value is always measured.

The present invention configured as described above can be used anywhere in the main pipe or chamber in which the liquid, which is the measurement target, is stored, to generate a change in the flow hydraulic pressure, and the representative device is the main pipe 10 of the ballast water treatment device of a ship.

That is, the present invention is particularly useful for a ballast water treatment device, the main pipe 10 of the ballast water treatment device is a place where changes in hydraulic pressure, flow rate, and flow rate can occur at any time, so the measurement of the TRO sensor in the prior art method Although the value error problem greatly influenced the operation of the ballast water treatment apparatus, the present invention can solve this problem.

Accordingly, when the main pipe or chamber in which the liquid as the measurement target of the present invention is stored is the main pipe 10 of the ballast water treatment device, the total residual oxide (TRO) of the ballast water treatment device of the main pipe 10 is reduced. It is to be provided a TRO sensor 20 that can constantly measure the total residual oxide concentration without errors due to the sampling flow rate and pressure fluctuation of the main pipe 10.

At this time, the atmospheric buffer chamber 40 reduces the load of the pump 30 for supplying the sample to the TRO sensor 20 by maintaining the sample seawater flowing from the main pipe 10 of the ballast water treatment apparatus in an atmospheric pressure atmosphere. At the same time, it helps to supply a constant flow rate, and it is possible to measure stable TRO concentration by minimizing the change of flow rate of sample seawater supplied into the sensor by not being affected by the change of operating conditions of the ballast water treatment system. do.

In addition, even when bubbles are contained in the sample seawater due to the change in the air pressure or the flow rate of the main pipe 10, the sample is removed from the atmospheric buffer chamber 40 and transferred to the TRO sensor, thereby making it possible to collect the sample seawater stably.

It will be apparent to those skilled in the art that the present invention may be embodied in many other specific forms without departing from the spirit or essential characteristics thereof.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit and scope of the invention as defined by the appended claims. It is to be understood that the technical spirit of the present invention is to the extent possible.

10: main pipe 20: TRO sensor
30: pump 40: atmospheric buffer chamber
400: pressure regulator tube 410: sampling pipe
420: outflow pipe

Claims (2)

The liquid flowing into the liquid inlet is transferred to the measuring unit cuvette through a solenoid valve to form a sample, and the sample is colored by supplying a buffer solution and a DPD color developing reagent to the cuvette, and the measuring sensor measures the amount of color development of the sample. A TRO sensor for measuring total residual oxide concentration by measuring;
A pump which is formed in an inlet pipe connected to the liquid inlet end of the TRO sensor and supplies liquid;
At the bottom of one side, a sampling pipe for collecting liquid from the main pipe or chamber in which the liquid to be measured is stored is connected. At the bottom of the other side, an outflow pipe connected to the pump is connected to temporarily store the sampled liquid. An atmospheric pressure control chamber is formed to communicate with the atmosphere to supply the liquid sample at a constant flow rate at atmospheric pressure to the pump.
Composed
Total residual oxide concentration sensor having a hydraulic flow rate buffer, characterized in that the measurement error caused by the variation of the sample flow rate and pressure is removed.
The total residual oxide concentration sensor having the hydraulic flow rate buffer according to claim 1, wherein
The main pipe of the ballast water treatment device is used as the main pipe or chamber in which the liquid to be measured is stored.
TRO sensor having a hydraulic flow rate rectifying buffer, characterized in that the total residual oxide (TRO) concentration of the ballast water treatment device can be constantly measured without errors due to sample flow rate and pressure fluctuations.

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