KR20140084999A - Device for measuring total residual oxidant of ballast water - Google Patents

Abstract

The present invention relates to a device for measuring residual chlorine of ballast water using an absorptiometric analysis. More specifically, the device for measuring residual chlorine includes: a purging unit for supplying purged ballast water to analysis units; a solution supplying unit for supplying an analysis solution for applying an absorptiometric analysis to the analysis units; and analysis units for mixing the ballast water supplied by the purging unit with the analysis solution supplied by the solution supplying unit to transmit light into the discolored ballast water and to measure and transfer the transmitted light to a controller. The analysis units are multiple in number and the ballast water is induced at predetermined time intervals to perform the measuring of residual chlorine without a delay in time.

Description

[0001] The present invention relates to a device for measuring residual chlorine concentration in ballast water,

The present invention relates to a residual chlorine concentration measuring apparatus for measuring the concentration of chlorine remaining in ballast water by using a spectrophotometric method and more particularly to an apparatus for measuring residual chlorine concentration, And an analyzing solution supplied from the solution supply unit to the ballast water supplied from the take-out furnace to irradiate the discolored ballast water with light and to transmit the transmitted light A plurality of analysis units are used, and each analysis unit receives ballast water at a time interval, and the number of ballast water that can measure the residual chlorine concentration of the ballast water in real time without delay time The present invention relates to a residual chlorine concentration measuring apparatus.

Ballast water means seawater filled in the ballast tanks in order to maintain the balance of the ship when the ship is operated without luggage. With the increase of international trade volume, the marine transportation ratio is increasing, and as the number of vessels increases and the size of vessels increases rapidly, the volume of ballast water used by vessels is greatly increasing. As the amount of ballast water used in vessels increases, the number of cases of harms caused by marine ecosystems due to foreign marine species is also increasing. In order to solve these international environmental problems, the International Maritime Organization (IMO) The International Convention on the Control and Management of Ballast Water and Sediments of Ships has been completed, and a new ballast water treatment system has been installed on ships newly constructed from 2009.

Conventionally, in order to prevent destruction of marine ecosystem caused by species contained in ballast water, the ballast water is sterilized by heat treatment, chemical treatment, electrolysis, and the like and discharged. In the case of the heat treatment method, there is a problem that it is difficult to treat heat-resistant microorganisms or inorganic pollution sources. In the case of the chemical treatment method, there is a problem that secondary pollution after the treatment of the ballast water may occur, And sterilizing the ballast water by feeding sterilized water generated by electrolysis to the ballast water is widely used.

In the conventional ballast water treatment system using the electrolysis method, since a certain amount of oxidizing agent remains in the ballast water discharged to the outside of the ship, the oxidizing agent remaining in the ballast water discharged to protect the marine ecosystem And discharges the ballast water to the outside of the ship after removing the residual oxidizing agent contained in the ballast water by supplying a neutralizing liquid in an amount suitable for neutralizing the concentration.

(Patent Literature)

Open Patent Publication No. 10-2007-0046440 (published on Mar. 03, 2007) "Electrolytic Ballast Water Treatment Method and Treatment Apparatus"

However, the NaOCl concentration measuring device for measuring the concentration of the oxidizing agent remaining in the ballast water requires a certain period of time, that is, a delay time, to collect and analyze the ballast water and discharge the concentration of the oxidizing agent remaining in the ballast water in real time It is impossible to supply an appropriate amount of neutralizing agent and there is a problem that the oxidizing agent remains in the ballast water discharged to the outside of the ship, thereby polluting the environment.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems,

An object of the present invention is to provide an apparatus for measuring residual chlorine concentration in ballast water capable of measuring residual chlorine concentration remaining in ballast water in real time without delay time.

In addition, since the present invention uses a plurality of analysis units and analyzes the ballast water flowing into each analysis unit at a time interval, it is possible to measure the residual chlorine concentration in the ballast water accurately, The purpose is to provide.

Another object of the present invention is to provide an apparatus for measuring residual chlorine concentration in ballast water, which can be economized by using one solution supply unit, a controller and a display.

In order to achieve the above object, the present invention is implemented by the following embodiments.

According to one embodiment of the present invention, an apparatus for measuring residual chlorine concentration in ballast water according to the present invention includes a take-out furnace for supplying the extracted ballast water to the analysis unit, a solution supply unit for supplying the analysis solution for the absorption spectrophotometric method to the analysis unit And an analysis unit which mixes the analysis solution supplied from the solution supply unit to the ballast water supplied from the take-out furnace to irradiate light to the discolored ballast water, measures the transmitted light, and transmits the measured light to the controller, A plurality of units are used, and the ballast water is introduced into each of the analysis units at intervals of time, and the residual chlorine concentration in the ballast water can be measured in real time without delay time.

According to another embodiment of the present invention, in the apparatus for measuring residual chlorine concentration in ballast water according to the present invention, when the analysis unit is N (N is a natural number of 2 or more) And the time interval of the ballast water has a value of the delay time / N.

According to another embodiment of the present invention, in the apparatus for measuring residual chlorine concentration in ballast water according to the present invention, when the delay time / N is 1 second, the concentration of chlorine remaining in the ballast water can be measured at intervals of 1 second .

According to still another embodiment of the present invention, in the apparatus for measuring residual chlorine concentration in ballast water according to the present invention, each of the analysis units includes a receiving cell in which ballast water and an analysis solution are supplied and mixed, A light source for irradiating light to the ballast water mixed with the solution and a photocell for measuring light passing through the ballast water irradiated from the light source and mixed with the analysis solution.

According to another embodiment of the present invention, in the apparatus for measuring residual chlorine concentration in ballast water according to the present invention, the analysis solution includes a buffer solution for controlling the pH and an indicator solution for changing the hue when the chlorine is left .

According to another embodiment of the present invention, in the apparatus for measuring residual chlorine concentration in ballast water according to the present invention, the receiving cell is formed of a transparent material that transmits light.

According to another embodiment of the present invention, in the apparatus for measuring residual chlorine concentration in ballast water according to the present invention, each of the analysis units includes a first control unit connected to the take-out passage to control the inflow of ballast water into the receiving cell Further comprising:

According to another embodiment of the present invention, an apparatus for measuring residual chlorine concentration in ballast water according to the present invention further comprises a discharge path connected to each of the analysis units, for discharging the analyzed ballast water.

According to another embodiment of the present invention, in the apparatus for measuring residual chlorine concentration in ballast water according to the present invention, one solution supply unit is used.

The present invention can obtain the following effects by the above-described embodiment, the constitution described below, the combination, and the use relationship.

The present invention has an effect that it is possible to measure the residual chlorine concentration remaining in the ballast water in real time without delay time.

In addition, since the present invention uses a plurality of analysis units and analyzes the ballast water flowing into the respective analysis units at intervals of time, it is possible to accurately measure the concentration of chlorine remaining in the ballast water in real time.

Further, the present invention has an effect of improving the economical efficiency by using one solution supply unit, a controller, and a display.

1 is a block diagram of a ballast water treatment system in which an apparatus for measuring residual chlorine concentration according to an embodiment of the present invention is used.
FIG. 2 is a configuration diagram of a bacteria water treatment system in which an apparatus for measuring residual chlorine concentration according to an embodiment of the present invention is used. FIG.
3 is a configuration diagram of an apparatus for measuring residual chlorine concentration according to an embodiment of the present invention.
4 is a reference diagram for explaining an apparatus for measuring residual chlorine concentration according to an embodiment of the present invention.

Hereinafter, an apparatus for measuring residual chlorine concentration in ballast water according to the present invention will be described in detail with reference to the accompanying drawings. It is to be noted that the same elements among the drawings are denoted by the same reference numerals whenever possible. Unless defined otherwise, all terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs and, if conflict with the meaning of the terms used herein, It follows the definition used in the specification.

FIG. 1 is a block diagram of a ballast water treatment system in which an apparatus for measuring residual chlorine concentration according to an embodiment of the present invention is used. FIG. 2 is a block diagram of a ballast water treatment system in which an apparatus for measuring residual chlorine concentration according to an embodiment of the present invention is used. FIG. 3 is a configuration diagram of an apparatus for measuring residual chlorine concentration according to an embodiment of the present invention, and FIG. 4 is a view for explaining an apparatus for measuring residual chlorine concentration according to an embodiment of the present invention. to be.

1 to 3, the ballast water treatment system according to an embodiment of the present invention includes a main stream pipe 1 through which ballast water flows, A sterilization water supply unit 3 for supplying a sterilized water to the main stream pipe 1 by withdrawing and electrolyzing a part of the ballast water from the main stream pipe 1, A neutralizing agent supply unit 4 for supplying a neutralizing agent for removing the oxidizing agent remaining in the ballast water discharged from the ballast tank 2; A residual chlorine concentration measuring device (5, 6) for measuring the concentration of the residual ballast water, and a control device (7) for controlling the operation of the ballast water treatment system, It is possible to measure the concentration in real time is characterized in that could generate the appropriate amount of sterile, and supplies a neutralizing agent improves the sterilization efficiency and the oxidizing agent the removal efficiency of the ballast water. Since the ballast water supplied to the bactericide supply part 3 has a salinity of a predetermined concentration or more, the bactericide supply part 3 can supply the chloric acid, the sodium hypochlorite, the sodium hypochlorite, etc. acting as the bactericide at the electrolysis of the ballast water Oxidant is produced.

The main stream pipe (1) is a pipe through which the main stream of ballast water moves, and includes an inlet pipe (11) and a discharge pipe (12).

The inflow pipe 11 is a tube for supplying the ballast water introduced into the ship to the ballast tank 2. The inflow pipe 1 is provided with sterilization containing sterilizing agent generated by the sterilization water supply unit 3 Which will be described in detail later. The intake pipe (11) is provided with a water intake pump (111).

The water intake pump 111 is installed at the tip side of the inflow pipe 11 and operates under the control of the control device 7 to transport the ballast water through the inflow pipe 11. The water intake pump 111 ) Output to control the flow rate of the ballast water transported through the inflow pipe (11).

The discharge pipe 12 is connected to the ballast tank 2 to discharge the ballast water to the outside of the ship. Since the oxidant remains in the ballast water discharged from the ballast tank 2, The neutralizing agent is supplied by the neutralizing agent supply unit 4, which will be described in detail below. The discharge pipe (12) is provided with a drain pump (121).

The drain pump 121 is installed in the discharge pipe 12 and operates under the control of the control device 7 to transport the ballast water through the discharge pipe 12.

The ballast tank 2 is connected to the end of the inflow pipe 11 and stores the ballast water mixed with sterilizing water containing a sterilizing agent transported through the inflow pipe 11. The ballast tank 2 may have a cylindrical shape, And may be formed of various materials such as SUS304 or SPV300. The ballast water stored in the ballast tank (2) is discharged to the outside of the ship through the discharge pipe (12).

The sterilization water supply unit 3 is configured to draw electrolytic water containing a sterilizing agent and to supply the electrolytic water to the main stream pipe 1 by withdrawing and electrolyzing a part of the ballast water from the main stream pipe 1, 31, an electrolysis section 32, a sterilization water supply pipe 33, and the like.

The outlet pipe 31 is connected to the inlet pipe 11 on the rear side of the intake valve 111 and connected to the inlet pipe 11 to supply a part of the ballast water flowing in the inlet pipe 11 to the electrolysis unit 32 A draw valve 311, a draw pump 312, and the like are installed in the take-out tube 31.

The take-out valve 311 is provided at the tip end side of the take-out tube 31 and operates under the control of the control device 7 to adjust the flow rate of the ballast water flowing through the take-out tube 31.

The drawing pump 312 is installed on the drawing pipe 31 on the rear side of the drawing valve 311 and operates under the control of the control device 7 to transport a part of the ballast water through the drawing tube 31 .

The electrolytic unit 32 receives the ballast water from the take-out pipe 31 and electrolyzes the ballast water to generate a sterilized water containing a sterilizing agent. The controller 7 controls the amount of sterilization water generated by regulating the operation of the electrolysis section 32 in accordance with the signal output from the residual chlorine concentration measuring device 5. [

The neutralizing agent supply unit 4 includes a neutralizing agent tank 41, a neutralizing agent supply pipe 42, a neutralization pump 43, and the like, configured to supply neutralizing agent to the ballast water discharged from the ballast tank 2. When a certain amount of oxidizing agent remains in the ballast water discharged from the ballast tank 2 and the ballast water is discharged to the outside of the ship without neutralization, the marine ecosystem is destroyed, and the neutralizing agent is supplied to the ballast water, The next ballast water is discharged to the outside of the ship.

In the neutralizer tank 41, a neutralizing agent for neutralizing the oxidizing agent is dissolved and stored. As the neutralizing agent, sodium sulfite, oxalic acid, and sodium thiosulfate may be used.

The neutralizer supply pipe 42 is connected to the neutralizer tank 41 at one end and connected to the discharge pipe 12 at the other end to supply the neutralizer.

The neutralization pump 43 is installed in the neutralizer feed pipe 42 and operates under the control of the control device 7 to transport the neutralizer through the neutralizer feed pipe 42. The control device 7 controls the operation of the neutralization pump 43 according to the signal output from the residual chlorine concentration measuring device 6 to control the amount of neutralizing liquid supplied to the discharge pipe 12.

The residual chlorine concentration measuring device 5 or 6 is configured to measure the concentration of the oxidizing agent in the ballast water flowing through the main stream pipe 1 and includes the residual chlorine concentration measuring device 5 And 6 are installed respectively in the inflow pipe 11 on the front side of the ballast tank 2 and the discharge pipe 12 on the rear side of the ballast tank 2. The residual chlorine concentration measured in the inflow pipe 11 The apparatus 5 and the residual chlorine concentration measuring device 6 provided in the discharge pipe 12 perform the same constitution and function only with different installation positions and therefore the residual chlorine concentration measurement Only the device 5 will be described. The residual chlorine concentration measuring device 5 is installed in the inflow pipe 11 on the rear side of the point where the sterilization water supply pipe 33 is connected and is located in the ballast water mixed with the sterilization water under the control of the control device 7 The solution supply section 52, the analysis unit 53, the discharge passage 54, the bypass passage 55, the controller 56, the display 57 and the like Wherein a plurality of the analysis units are used, and the ballast water is introduced into each of the analysis units at intervals of time, and the residual chlorine concentration in the ballast water can be measured in real time without delay time. The time interval of the ballast water introduced into each of the analysis units has a value of a delay time / N when the analysis unit is N (N is a natural number of 2 or more).

The takeout passage 51 is connected to the inlet pipe 11 and is connected to the take-out pipe A for discharging the ballast water to supply the ballast water to the analysis unit 53. The takeout passage 51 Is connected to each of the plurality of analysis units 53 to supply the ballast water.

The solution supply unit 52 supplies the analysis solution to the analysis unit 53 through the single solution supply unit 52 with the configuration for supplying the analysis solution for the absorption spectrophotometric method to the analysis unit 53. The solution supply part 52 includes a buffer solution tank 521 and an indicator solution tank 522.

The buffer solution tank 521 stores a buffer solution for controlling the pH of a fluid located in the receiving cell 531 of the analysis unit 53. The buffer solution stored in the buffer solution tank 521 is a solution The pH of the fluid supplied to the receiving cell 531 and located in the receiving cell 531 has a value of approximately 5 to 6.6.

The indicator solution tank 522 is configured to store an indicator solution in which the color changes according to the concentration of chlorine in the fluid located in the receiving cell 531 of the analysis unit 53, diethyl-p-phenylenediamine (DPD) is used.

The analysis unit 53 irradiates light to the discolored ballast water by mixing the analysis solution supplied from the solution supply part 52 to the ballast water supplied from the take-out furnace 51, measures the transmitted light, 56 and each of the analyzing units 53 is provided with a receiving cell 531, a light source 532, a photocell 533, a first adjusting unit 534, A third adjustment unit 536, a fourth adjustment unit 537, and the like.

The receiving cell 531 receives the ballast water supplied from the takeout passage 51 and the analysis solution supplied from the solution supply unit 52 to mix the ballast water and the analysis solution. ) Is made of a certain material, but is preferably made of a transparent material that transmits light.

The light source 532 is disposed outside the receiving cell 531 and irradiates light to the ballast water mixed with the analysis solution located in the receiving cell 531. The light emitted from the light source 532 Is preferably in the range of 490 to 530 nm.

The photocell 533 is located outside the receiving cell 531 and measures the light passing through the ballast water irradiated by the light source 532 and mixed with the analysis solution to generate an electrical signal, ).

The first adjusting unit 534 is connected to the takeout passage 51 to adjust the inflow of the ballast water into the receiving cell 431. The second adjusting unit 535 is connected to the discharge passage 54, And the third control unit 536 controls the discharge of the buffered water supplied from the buffer solution tank 521 to the receiving cell 431. The third control unit 536 controls the discharge of the analyzed ballast water in the receiving cell 431, And the fourth adjusting unit 537 controls the inflow of the indicating solution supplied to the containing cells 431 from the indicating solution tank 522. [ A pump or a valve may be used as the first adjusting unit 534, the second adjusting unit 535, the third adjusting unit 536, and the fourth adjusting unit 537. It is possible to introduce the ballast water into each of the injection units 53 with a time interval by adjusting the first adjustment portion 534 of each of the injection units 53. [

The discharge passage 54 is connected to each of the analysis units 53 so that the analyzed ballast water moves. The analyzed ballast water is discharged to the outside through the discharge passage 54.

The bypass path 55 is connected to the take-out passage 51 to bypass the ballast water flowing into the measuring device 5. [

The controller 56 controls the overall operation of the measuring device 5 and analyzes the measured values from the analyzing unit 53 to calculate the residual chlorine concentration and display its value via the display 57. [

For example, as shown in FIG. 4, the analysis unit may be referred to as three (each of the three analysis units is referred to as a first analysis unit 53, a second analysis unit 53 ', and a third analysis unit 53' ), And the time taken for the photocell to measure the light passing through the ballast water and to transmit the signal to the controller, that is, the delay And the time is assumed to be 60 seconds, the principle of measuring the residual chlorine concentration in the residual chlorine concentration measuring apparatus having the above configuration will be described.

The controller 56 controls the first adjusting unit 534, the third adjusting unit 536 and the fourth adjusting unit 537 of the first analyzing unit 53 to adjust the first analyzing unit 53 The pH of the ballast water in the receiving cell 531 is adjusted and the color of the ballast water in the receiving cell 531 changes according to the amount of chlorine remaining in the receiving cell 531 do. Thereafter, the controller 56 operates the light source 532 of the first analysis unit 53 to irradiate the ballast water in the receiving cell 531 with light, and the photo cell 533 transmits the ballast water The controller 56 calculates the concentration of chlorine remaining in the ballast water and displays the calculated concentration on the display 57. [ Thereafter, the controller 56 adjusts the second adjusting unit 535 to discharge the analyzed ballast water through the discharge path 54, and supplies the ballast water and the analysis solution to the first analysis unit 53 again To continuously measure the residual chlorine concentration of the ballast water. Accordingly, in the first analysis unit 53, the concentration of the ballast water flowing into the take-out tube 100 at an interval of 60 seconds is analyzed.

In addition, the controller 56 controls the first adjusting unit 534 ', the third adjusting unit 536', and the fourth adjusting unit 537 'of the second analyzing unit 53' The ballast water flowing into the take-out tube 100 after 20 seconds (delay time / number of analysis units) later than the ballast water supplied to the first analysis unit 53 in the receiving cell 531 'of the analysis unit 53' And the analysis solution are supplied, the ballast water in the receiving cell 531 'is adjusted in pH and changed in color depending on the amount of residual chlorine. Thereafter, the controller 56 operates the light source 532 'of the second analysis unit 53' to irradiate the ballast water in the receiving cell 531 'with light, and the photocell 533' The controller 56 determines that the ballast water has flowed into the take-out tube 100 at a time 20 seconds later than the ballast water that has been analyzed in the first analysis unit 53 The chlorine concentration remaining in the ballast water is calculated and displayed on the display (57). Thereafter, the controller 56 adjusts the second adjusting unit 535 'to discharge the analyzed ballast water through the discharge path 54, and the second analysis unit 53' To continuously measure the residual chlorine concentration of the ballast water. Therefore, in the second analysis unit 53 ', the ballast water that has flowed into the take-out tube 100 at a delay time of 60 seconds later than the ballast water that has been analyzed in the first analysis unit 53 by 20 seconds The concentration is analyzed.

In addition, the controller 56 controls the first adjusting unit 534 ", the third adjusting unit 536 ", and the fourth adjusting unit 537 "of the third analyzing unit 53" The ballast water introduced into the take-out tube 100 late 20 seconds (delay time / number of analysis units) later than the ballast water supplied to the second analysis unit 53 'in the receiving cell 531 "of the analysis unit 53" When the water and the analysis solution are supplied, the ballast water in the receiving cell 531 "is adjusted in pH and the hue changes according to the amount of residual chlorine. The light source 532 " of the photocell 533 "is operated to irradiate the ballast water in the receiving cell 531 ", and the photocell 533" The concentration of chlorine remaining in the ballast water flowing into the take-out tube 100 is calculated 20 seconds later than the ballast water which has been received and analyzed in the second analysis unit 53 ' It is displayed on the display 57.

Thereafter, the controller 56 adjusts the second adjuster 535 " to discharge the analyzed ballast water through the discharge passage 54, and the third analysis unit 53 " To continuously measure the residual chlorine concentration of the ballast water. Therefore, in the third analysis unit 53 ", the ballast water flow rate which is 20 seconds later than the ballast water that was analyzed in the second analysis unit 53 " Is analyzed.

As described above, when three analysis units 53, 53 ', 53 "are used and the delay time of one analysis unit is 60 seconds, the analysis units 53, 53', 53" If the ballast water is supplied at intervals, the delay time of the analyzer can be reduced to 20 seconds. Therefore, when the analysis unit 53 uses N (N is a natural number of 2 or more), the time interval of the ballast water flowing into each of the analysis units 53 has a value of the delay time / N The delay time can be reduced to the delay time / N. For example, when the value of the delay time / N is 1 second, it is possible to measure the concentration of chlorine remaining in the ballast water at intervals of 1 second.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, Should be interpreted as falling within the scope of.

1: Mainstream pipe 11: Inflow pipe 12:
2: Ballast tank 3: Sterilization water supply part 31: Drawing tube
32 electrolysis unit 33 electrolytic water supply pipe 4 neutralizing agent supply unit
41: neutralizer tank 42: neutralizer feed pipe 43: neutralization pump
5, 6: residual chlorine concentration measuring device 51: take-out furnace 52:
53: analysis unit 54: discharge path 55: bypass path
56: controller 57: display 7: control device

Claims (9)

A residual chlorine concentration measuring device for measuring the concentration of chlorine remaining in ballast water by using an absorption spectrophotometer,
The residual chlorine concentration measuring device includes a take-out furnace for supplying the extracted ballast water to the analysis unit, a solution supply part for supplying the analysis solution for the absorption spectrophotometric application to the analysis unit, And an analysis unit for irradiating the discolored ballast water with light, measuring the transmitted light, and transmitting the measured light to the controller,
Wherein a plurality of analysis units are used and each analysis unit is capable of measuring the residual chlorine concentration in the ballast water in real time by reducing the delay time by introducing the ballast water at a time interval and measuring the residual chlorine concentration in the ballast water. The method according to claim 1,
Wherein the time interval of the ballast water introduced into each of the analysis units has a value of a delay time / N when the analysis unit uses N (N means 2 or more natural numbers) Concentration measuring device. 3. The method of claim 2,
Wherein the concentration of chlorine remaining in the ballast water can be measured at intervals of 1 second when the value of the delay time / N is 1 second. 3. The apparatus of claim 2, wherein each of the analysis units
A light source for irradiating light to the ballast water mixed with the analysis solution located in the receiving cell, and a ballast water which is irradiated from the light source and mixed with the analysis solution is passed Wherein the residual chlorine concentration in the ballast water is measured by a photocell. 5. The method of claim 4,
Wherein the analysis solution comprises a buffer solution for controlling the pH and an indicator solution for changing the color of the residual chlorine when the residual chlorine is changed. 6. The apparatus of claim 5,
Wherein the residual chlorine concentration measuring unit is formed of a transparent material that transmits light. 7. The apparatus of claim 6, wherein each of the analysis units
Further comprising a first control unit connected to the take-out passage to control the inflow of the ballast water into the receiving cell. The apparatus according to claim 7, wherein the residual chlorine concentration measuring device
Further comprising an exhaust passage connected to each of the analysis units for discharging the analyzed ballast water. 9. The process cartridge according to any one of claims 1 to 8,
Wherein the residual chlorine concentration in the ballast water is measured by a sensor.

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