KR101918570B1 - TRO Sensing Equipment for Ballast water - Google Patents

Abstract

The present invention relates to a sensing device for checking a total residual oxidant (TRO) value contained in ballast water, and more specifically relates to a TRO sensing device for ballast water, in which a flow pipe is installed at one side of a ballast water line where seawater is introduced and discharged, and a flow of the ballast water is stopped by a solenoid valve after inputting an agent into the ballast water flowing along the flow pipe and flowing the ballast water for a certain time after the input of the agent, such that the TRO value can be measured by using the concentration of color discolored in accordance with the input of the agent.

Description

Technical Field [0001] The present invention relates to a TRO sensing device for ballast water,

The present invention relates to a sensing device for confirming a total residual oxidant (TRO) value contained in ship equilibrium water, and more particularly, to a sensing device for detecting a total residual oxidant The reagent is introduced into the ballast water flowing along the flow pipe, the ballast water is flowed for a predetermined time after the introduction of the reagent, the flow of the ballast water is stopped by the solenoid valve, and the concentration of the discolored color Is a ballast water TRO sensing device capable of measuring the TRO value.

In general, ballast water refers to seawater stored inside a vessel to maintain the balance of the vessel.

Such ship equilibrium water is filled with seawater to the left and right ballast tanks in order to prevent the floating of the ship and to balance the ship, and it moves to another port. When the cargo is loaded, The water is thrown into the sea.

Any discharge of such ship equilibrium water can disturb the marine ecosystem. That is, various kinds of marine microorganisms inhabited in the place where the ballast water is collected are naturally moved to another place or a third country along with the voyage, thereby causing disruption of distribution of marine microorganisms. For example, marine microorganisms contained in ship equilibrium water are discharged along with marine equilibrium water in the sea of a third country, and show vigorous reproduction when they adapt to the environment of the discharge area. As a result, marine microorganisms introduced from other regions are naturally incarnated in the sea area and spread to neighboring sea areas, and the native marine living resources are greatly affected. It may be desirable if a situation occurs in which the balance between incoming alien species and indigenous species occurs, but the reality is not so that the damage of native species can cause a great change in the ecosystem food chain and the economic loss May occur. In other words, the introduction of foreign marine microorganisms leads to an undesirable change of the marine ecosystem, which in turn affects the human life of the sea. Therefore, there is an increasing demand for a technique for removing marine microorganisms by sterilization treatment before discharge of ship ballast water.

Meanwhile, the International Maritime Organization (IMO) has established the Convention on Ship Ballast Water Management (BWMS) in 2004 to prevent such problems. The Convention is expected to enter into force on September 8, 2017, as Finland has agreed to ratify the World BWMS (BWMS) on September 8, 2016. The Convention prohibits the discharge of ballast water from untreated ports in other countries. It also requires the establishment of a ship's ballast water treatment facility (BWTS) in ships carrying international voyages. 50,000 ships carrying international voyages must install BWTS before 7 September 2022. Boats constructed after the entry into force of the Convention shall have BWTS installed at the stage of construction.

As a related art related to this, there is a ship ballast water treatment apparatus proposed in Patent Registration No. 10-1763351.

The patent includes a seawater inflow line for inflowing seawater from the outside; A ship ballast water storage unit for storing the seawater introduced from the seawater inflow line; An electrolysis unit for electrolyzing a part of seawater flowing into the inflow line to generate treated water; A process water storage unit for storing the process water electrolyzed from the electrolysis unit; A salinity measuring unit for measuring a saline value (psu) value of seawater flowing from the seawater inflow line; A salt water storage part for storing saline water to be supplied to the electrolysis part; A chemical storage unit for storing an oxidizing agent to be supplied to the seawater inflow line; A control unit for generating a control signal for controlling an amount of treated water flowing out of the driving and treating water storage unit of the electrolysis unit according to the actual salt value (psu) measured by the salt measuring unit; And a dilution line for mixing the treated water with seawater flowing into the seawater inflow line, wherein when the actual salinity (psu) value measured by the salinity measurer is 30 or more, the control unit controls the electrolysis unit And when the measured salinity (psu) value measured by the salinity measuring unit is in the range of less than 30 to over 10, the control unit controls the electrolysis unit to output the flow rate signal of the treated water to the driving signal of the electrolysis unit and the process water storage unit The control unit transmits a signal indicating the flow rate of the treated water to the treated water storage unit when the measured salinity (psu) value is less than 10 measured by the salinity measuring unit. And transmits a signal for inputting the medicine of the medicine storage section to the seawater inflow line. However, only the measurement of the actual salinity (psu) By determining whether the driver's mood, and the problem can not be guaranteed for the proper removal efficiency of marine microorganisms, it is impossible to measure the exact value TRO.

In order to solve such a problem, Japanese Patent Registration No. 10-1731505 discloses a high-performance TRO sensor for ballast water treatment and a driving method thereof.

This patent discloses a high performance TRO sensor for ballast water treatment, comprising: a first pipe 100 through which seawater flowing from a seawater inlet 10 flows; A filtration filter 20 for filtering the seawater introduced from the seawater inlet 10; An electrolytic apparatus (200) for injecting hypochlorite (S) generated by electrolyzing seawater into the first pipe (100); A ballast tank 300 for storing seawater mixed with hypochlorite S; A second pipe 120 for discharging the ballast water stored in the ballast tank 300; A neutralizer injection device 400 for injecting the neutralizer N into the second pipe 120; A neutralizing agent injection control unit 410 for controlling the neutralizing agent injection amount of the neutralizing agent injecting apparatus 400; A warning signal unit 420 for transmitting a warning signal during over or under injection of the neutralizing agent N; A TRO sensor 500 for measuring hypochlorite (S) concentration of seawater flowing into and out of the ballast tank 300; A reagent part 510 provided at one side of the TRO sensor 500 for keeping the N, N-diethyl-p-phenylenediamine salt indicating reagent (D) for the hypochlorite (S) concentration measurement in a hermetic state; A flow regulator 520 for injecting seawater into the TRO sensor 500 at a constant flow rate; A vibration damper 530 for absorbing external vibration applied to the TRO sensor 500; A cleaning unit 540 for cleaning the seawater remaining in the TRO sensor 500; A sensor control unit 550 for remotely diagnosing and controlling the TRO sensor 500; An embedded-based monitoring unit 560 for interfacing with the sensor control unit 550 to transmit and receive status information and control commands; A mixing device (600) for mixing the hypochlorite (S) and the seawater; And a neutralizing agent mixing device 700 for mixing the neutralizing agent N injected by the neutralizing agent injecting device 400 with the drain water. A high performance TRO sensor for ballast water treatment has been proposed, It is necessary to clean the residual seawater in the sensor by the cleaning unit 540 and then inject new seawater into the TRO sensor again, so that the sensing time is delayed.

That is, if the sensing time of the TRO sensor is delayed, an error occurs in measuring the concentration of hypochlorite (S) contained in the seawater, which causes a fundamental problem that proper seawater treatment can not be performed.

Another prior art related to the TRO sensor is the continuous measurement type TiO2 measuring device proposed in Japanese Patent Registration No. 10-1303349.

The housing includes a sensing unit connected to a water supply pipe and measuring a total residual oxidant (TRO) concentration of the water in the water intake pipe, An inlet and an outlet connected to the housing for introducing the collected water flowing through the inside of the water supply pipe into the housing or flowing into the housing and discharging the collected water whose total concentration of residual oxidant is measured by the sensing unit to the outside of the housing; Wherein the sensing unit comprises a reagent charging unit for charging the DPD reagent into the collection water introduced into the housing through the inlet and outlet water chambers, a DPD reagent supply unit for supplying the DPD reagent from the reagent charging unit, The concentration side for measuring the concentration of total residual oxidant by transmitting light through this charged water And a display unit for displaying the concentration of total residual oxidant in the water sampled from the concentration measuring unit. The DPRO reagent is introduced into the water flowing through the inlet and outlet water chambers Therefore, the reagent is wasted so much that the reagent is continuously injected and measured, so that the reagent is discharged in a state in which the reagent is not mixed with the water, so that it is impossible to accurately measure the TRO concentration.

Korean Patent Publication No. 10-1763351 Korean Patent Publication No. 10-1731505 Korean Patent Registration No. 10-1303349

Therefore, in the present invention, a flow pipe is installed on one side of a ballast water line into which seawater flows or flows out, a reagent is put into the ballast water flowing along the flow pipe, a ballast water is flowed for a predetermined time after the introduction of the reagent, Which is capable of increasing the accuracy of the measured TRO value by stopping the flow of the ballast water by measuring the TRO value according to the concentration of the discolored hue according to the input of the reagent .

Another object of the present invention is to provide a ballast water TRO sensing device having a check valve installed on both sides of a flow pipe to increase the accuracy by measuring the TRO value while the ballast water flowing along the flow pipe is stopped.

Another object of the present invention is to provide a ballast water TRO sensing device in which the flow tube is bent at least two times so that the reagent injected from the reagent injector and the sea water flowing along the flow pipe are naturally stirred.

Another object of the present invention is to provide a ballast water TRO sensing device that does not require a separate drain tank by discharging the seawater flowing along the flow pipe to the ballast water line along the discharge pipe after measuring the reagent .

A ballast water TRO sensing device according to the present invention is a sensing device used for controlling a TRO value contained in ship ballast water. The sensing device includes an inflow pipe communicating with a ballast line to receive seawater, A reagent injector installed at one side of the flow pipe for introducing the reagent, a photosensor for measuring the concentration discolored due to the introduced reagent, and seawater flowing along the flow pipe toward the ballast water line And a discharge pipe for discharge.

A ballast water TRO sensing device according to the present invention is characterized in that a flow pipe is installed at one side of a ballast water line through which seawater flows in or out and a reagent is put into ballast water flowing along the flow pipe, There is a remarkable effect that the accuracy of the measured TRO value can be increased by stopping the flow of the ballast water by the check valve after the passage of time and measuring the TRO value by the concentration of the color discolored by the introduction of the reagent, A check valve is provided on both sides of the flow pipe to measure the TRO value in a state where the ballast flowing along the flow pipe is stopped to improve the accuracy. In addition, the flow pipe forms a bent part bent twice or more, And the sea water flowing along the flow pipe are naturally stirred.

1 and 2 are overall block diagrams of a ballast water treatment apparatus in which the present invention is used
3 is a schematic configuration diagram of the present invention

The present invention relates to a sensing device for confirming a total residual oxidant (TRO) value contained in ship equilibrium water, and more particularly, to a sensing device for detecting a total residual oxidant The reagent is introduced into the ballast water flowing along the flow pipe, the ballast water is flowed for a predetermined time after the introduction of the reagent, the flow of the ballast water is stopped by the solenoid valve, and the concentration of the discolored color Is a ballast water TRO sensing device capable of measuring the TRO value.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a view showing a ballast water flow during ballasting, and FIG. 2 is a view showing a ballast water flow during dribbling .

FIG. 1 is a view showing a ballast water flow in a ballast tank in which ballast water flows into the ballast tank. Referring to a ballast water treatment apparatus to which the present invention is applied, a ballast water inflow port (not shown) communicating with a ballast water line The seawater is introduced, and the seawater is moved through a pump formed on one side of the ballast water line. Sands and suspended matters contained in seawater are primarily filtered by a filter, and microorganisms and the like contained in the ballast water are sterilized by an electrolytic apparatus formed on one side of the ballast water line.

That is, in the electrolytic apparatus, chlorine ion (Cl ^- ) of sea water is oxidized to generate chlorine gas (Cl ₂ ) at the anode, oxygen gas and hydrogen ion (H ⁺ ) are generated by decomposition of water as a side reaction, In the cathode, water is decomposed and hydrogen hydroxide ion (OH ^- ) is generated when hydrogen gas is generated. The chlorine gas is dissolved by the solution to produce sodium hypochlorite (NaOCl), and this sodium hypochlorite removes the microorganisms inside the equilibrium water.

The sodium hypochlorite (NaOCl) produced by the electrolytic unit is injected into the ballast water line to disinfect the ballast water. Then, the TRO sensor formed on one side of the ballast water line removes the TRO (Total Residual Oxidant) Value is sensed.

The value sensed by the TRO sensor is used to determine the concentration of sodium hypochlorite to be produced by the electrolytic device and it is then possible to prevent the concentration of sodium hypochlorite from exceeding the discharge standard when discharging the ballast water.

FIG. 2 is a diagram showing the ballast water flow during the diballust for discharging the ballast water to the outside of the ship. The seawater in the ballast tank is discharged to the outside through the ballast water line, the neutralizing agent is supplied to the neutralizer tank, The TRO value of the seawater into which the neutralizing agent is introduced is measured and discharged through the discharge line.

At this time, the value measured by the TRO sensor is a function value for determining the amount of the neutralizer introduced into the neutralizer adder.

Therefore, the TRO value measured by the TRO sensor used when the seawater is introduced into the ballast tank or discharged to the outside is an important factor for determining the generation amount of sodium hypochlorite or the amount of the neutralizer to be sterilized. The sensing time is usually 1 to 2 minutes, so that a real-time response due to inflow and outflow of seawater is delayed, and thus a proper response can not be provided.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the attached drawings.

A ballast water TRO sensing device according to the present invention is a sensing device used for controlling a TRO value contained in ship ballast water. The sensing device includes an inflow pipe (11) communicating with the ballast water line (1) A flow pipe 12 installed at one side of the inflow pipe 11 and flowing a ballast water, a reagent injector 17 installed at one side of the flow pipe 12 for injecting the reagent, And a discharge pipe 13 for discharging the seawater flowing along the flow pipe 12 toward the ballast water line 1. [

The inflow pipe 11 is connected to the ballast water line 1 and flows a predetermined amount of seawater into the inflow pipe 11. The inflow pipe 11 is connected to the flow pipe 12 And a discharge pipe 13 is formed at one side of the flow pipe 12 so that the ballast water passing through the flow pipe 12 enters the ballast water line 1 again.

A reagent injector 17 for injecting a DPD reagent, which is conventionally used for a reagent, a TRO sensing device, is provided on one side of the flow pipe 12, and a reagent injector 17 is disposed behind the reagent injector 17 An optical sensor 18 is provided to measure the concentration of the color of the equilibrium color discolored by the reagent injected from the reagent injector 17.

Since the solenoid valve 15 and the check valve 16 are provided at one side of the flow pipe 12 to control the flow state of the ballast water flowing along the flow pipe 12, It is characterized by sensing the TRO value.

That is, the reagent is supplied in a state in which the ballast water flowing through the inflow pipe 11 flows through the flow pipe 12, and the solenoid valve 15 is closed after the ballast water of the portion into which the reagent is injected reaches the optical sensor 18. [ It is possible to sense a more accurate TRO value by sensing the TRO value in a state in which the ballast water is prevented from flowing through the flow pipe 12.

In other words, when the TRO value is sensed while the ballast water continues to flow, an inaccurate value can be sensed by continuously changing the TRO value, that is, the color density of the ballast water. The flow of the ballast water is detected by the solenoid valve 15 This problem can be avoided by sensing the state with the check valve 16 stopped.

In addition, the optical sensor 18 senses a certain time after the reagent is injected in consideration of the flow rate of the ballast water flowing along the flow pipe 12 at the reagent injecting point by the reagent injector 17, It is desirable to measure the TRO value.

The flow tube 12 is folded more than twice and flows through the bent portion 12a of the flow tube 12 with the reagent flowing naturally from the point where the reagent injector 17 is installed to the optical sensor 18, It is characterized by being stirred.

That is, in the case of the flow pipe 12, a relatively small amount of equilibrium water flows because it is a concept of branching at the equilibrium water line (1). As a result, a separate device such as a stirrer And it is possible to prevent the flow of the ballast water when a filter or the like for stirring is put into the flow pipe 12.

Therefore, if the flow pipe 12 itself is bent more than twice without a separate device, the flow of the ballast water in the bent portion 12a becomes unnatural and vortex or the like appears, so that the stirring of the reagent and the ballast water can be performed quickly By this stirring, a more accurate TRO value can be sensed.

The flow rate of the ballast water flowing along the flow pipe 12 is calculated by using the cross-sectional area and the flow rate of the pipe, and the flow rate is calculated by measuring the pressure of the rear end of the fluid pump 14 installed at one side of the inflow pipe 11 to be.

That is, as described above, in the case of the flow pipe 12, the diameter of the pipe is relatively smaller than that of the ballast water line 1, so that the flow rate detection by the flow rate sensor may be inaccurate. The flow rate can be determined by using the cross-sectional area of the flow pipe and the distance between the check valve 16 and the check valve 16. [

In addition, the flow rate can be determined by measuring the pressure at the rear end of the fluid pump 14 installed at one side of the inflow pipe 11 so that the flow rate of the ballast water can be finally confirmed. As a result, The time to reach the sensor 18 can be easily calculated.

3, a check valve 16 is installed on both sides of the flow pipe 12. A flow pipe 12 on the side of the discharge pipe 13 is connected to a sensing unit 12b And the flow of the ballast water is stopped by the fluid pump 14 and the solenoid valve 15, the ballast water is naturally trapped in the inside of the flow pipe 12. Therefore, even if a solenoid valve or a check valve is not provided on the side of the discharge pipe 13, the ballast water in the sensing unit 12b, which is sensed by the optical sensor 18 due to the self weight of the ballast water, The non-flowing state can be maintained.

Therefore, when the reagent is introduced by the reagent injector 17 and the sensing of the TRO value is completed by the optical sensor 18, the fluid is pumped by the fluid pump 14 and the solenoid valve 15 for a predetermined time The reagent remaining in the flow pipe 12 can be completely removed and the measurement can be performed again. As a result, it is possible to perform the cleaning in an early time and to perform an accurate measurement. Further, There is no need to store a tank.

The unexplained reference numerals can be configured to display a TRO value measured in real time by the display unit 19 or to show a graph of a change in flow rate, flow rate, and TRO value of the ballast water.

In the above-described embodiments, the present invention is applied to an electrolytic ballast apparatus. However, it is obvious that the present invention can also be applied to a ballast apparatus for sterilizing ozone.

Further, in one cycle of the TRO sensing apparatus according to the present invention, about two seconds are required to put the ballast water into the flow tube and inject the reagent, and the solenoid valve 15 is closed, the fluid pump 14 is stopped, It takes about 8 seconds to sense by the sensor 18 and then about 2 seconds to clean the flow pipe by injecting only the ballast water thereafter so that it can be sensed in a time unit of about 12 seconds and the TRO Can be accurately sensed.

As a result, in the ballast water TRO sensing apparatus according to the present invention, a flow pipe is installed on one side of a ballast water line through which seawater flows in or out, a reagent is put into ballast water flowing along the flow pipe, The flow of the ballast water is stopped by the check valve after a certain period of time, and the TRO value is measured by the density of the discolored color in response to the introduction of the reagent, whereby the accuracy of the measured TRO value can be enhanced. By providing a check valve on both sides of the flow pipe, it is possible to increase the accuracy by measuring the TRO value while the ballast water flowing along the flow pipe is stopped. In addition to this effect, the flow pipe forms a bent part bent twice or more, There is a remarkable effect that stirring of the introduced reagent and seawater flowing along the flow pipe is naturally performed.

1. Ballast water line 2. Pump
3. Filter 4. Electrolysis device
5. Ballast tank 6. Neutralizer input
10; TRO sensor
11. Inflow pipe 12. Flow pipe
12a. The bent portion 12b. Sensing portion
13. Discharge tube 14. Fluid pump
15. Solenoid Valve 16. Check Valve
17. Reagent dispenser 18. Optical sensor
19. Display unit

Claims (6)

A sensing device used for controlling a TRO value contained in ship ballast water,
An inflow pipe 11 communicating with the ballast water line 1 and introducing seawater into the inflow pipe 11; a flow pipe 12 installed at one side of the inflow pipe 11 to flow the ballast water; An optical sensor 18 for measuring the concentration discolored by the introduced reagent and a discharge pipe 18 for discharging seawater flowing along the flow pipe 12 toward the ballast water line 1, (13), there is no separate drain tank,
A solenoid valve 15 and a check valve 16 are provided on one side of the flow pipe 12 to control the flow state of the ballast water flowing along the flow pipe 12 so that the TRO value Sensing,
The reagent is supplied in a state in which the ballast water flowing through the inflow pipe 11 flows through the flow pipe 12 and the solenoid valve 15 is closed after the ballast water of the portion into which the reagent is injected reaches the optical sensor 18 It is possible to sense a more accurate TRO value by sensing the TRO value in a state where the ballast water is confined in the flow pipe 12 so that the ballast water can not flow through the ballast tank 12,
The optical sensor 18 senses a certain time after the reagent is injected considering the flow rate of the ballast water flowing along the flow pipe 12 at the reagent injecting point by the reagent injector 17,
The flow tube 12 is bent twice or more and is naturally stirred with the reagent through the bent portion 12a of the flow tube 12 while the ballast water flows from the point where the reagent injector 17 is installed to the optical sensor 18 The flow of the ballast water can not be naturally flowed by the bending portion 12a bent twice or more and the vortex is generated, so that the stirring of the reagent and the ballast water can be rapidly performed. And a TRO value of an accurate value can be sensed.
delete delete delete delete The method according to claim 1,
A check valve 16 is installed on both sides of the flow pipe 12 and the flow pipe 12 on the side of the discharge pipe 13 is formed higher than the sensing unit 12b which is sensed by the optical sensor When the flow of the ballast water is stopped by the fluid pump 14 and the solenoid valve 15, the ballast water is naturally trapped inside the flow pipe 12, And the ballast water TRO sensing device is capable of maintaining a non-flowing state during sensing.

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