KR101655795B1 - Marine growth prevention system with fresh water generator within low slat sea water environmet - Google Patents

Abstract

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above-mentioned problems of the related art in that, when a ship is anchored near a land for a long time (that is, when the ship is exposed to a low-salt sea water environment) Which is a device for preventing the propagation of marine organisms contained in the seawater due to the concentration of the salt contained therein being lower than that of the salt contained in ordinary seawater. When the salt is exposed to the seawater environment, it is introduced into the MGPS without discharging seawater having high salinity discharged from the water purifier. When the concentration of the salt contained in the seawater discharged from the water generator is not sufficiently high, the seawater discharged from the water generator is not discharged to the outside of the ship, but is recycled to the recycle tank, The present invention relates to an apparatus for preventing marine organisms from being used in a low-salt sea water environment capable of supplying seawater having a salt concentration of at least a predetermined level to the MGPS, It is possible to provide a method for effectively preventing the propagation of marine organisms even when the marine vessel is exposed to low-salt marine environment.

Description

Technical Field [0001] The present invention relates to an apparatus for preventing marine organisms from adhering to a low salt water environment using a fresh water generator, and a method for preventing marine organisms from adhering to a marine organism using the same,

The present invention relates to a method and apparatus for preventing marine organisms (MGPS) from operating in a low-salt water environment by using seawater and seawater circulation devices, And to a method for preventing the attachment of marine organisms in a low salt sea water environment using the same.

If seawater is directly introduced into the piping or apparatus constituting the cooling system of the ship, the marine life in the seawater is adhered to cause damage to the inside of the piping or apparatus or clogging of the piping. In order to solve these problems, Marine Growth Prevention System (MGPS), which is a device for preventing various marine organisms from being fixed through chemical methods, is generally used.

1 shows a seawater supply system 10 installed on an existing ship used in a ship. The seawater supply system 10 generally includes a marine life prevention apparatus 20 (MGPS) and a water purifier 30 do.

The fresh water generator (FWG) 30 is a device for producing fresh water 31 required in a ship, and is a device for generating fresh water by evaporating seawater by using high heat such as waste heat of a ship engine jacket.

Generally, when 100% of the seawater is supplied to the water generator 30, about 80% of the water is discharged to the outside of the ship (32) at the same level as that of ordinary seawater, and about 20% Only.

In order to supply seawater to such a fresh water generator, a seawater supply pump 40 for supplying seawater from the seaweed 50 is used. In this case, the marine life included in the supplied seawater may cause contamination of the above- The MGPS 33 and 34 are additionally provided between the seawater supply pump 40 and the body sash 50 as disclosed in Japanese Laid-Open Patent Publication No. 2010-0043876.

Therefore, when the seawater is supplied to the body strut 50, the supplied seawater passes through the MGPS 20, 33 and 34, thereby preventing the marine life in the seawater from propagating.

The basic operation principle of the MGPS 20, 33, and 34 is to electrolyze NaCl in the salt contained in seawater to produce chlorine and hypochlorite, and to produce a strong germicidal or insecticidal property Will prevent the propagation of marine organisms within the pipelines and devices to which seawater is supplied.

Anodic reaction: 2Cl ^- → Cl ₂ + 2e, Cl ₂ + H ₂ O → HCl + HClO

Cathode reaction ^{(cathodic reaction): 2Na + +} 2H 2 O + 2e → 2NaOH + H 2

The chlorine produced in the anodic reaction reacts with caustic soda produced in the cathode part as follows to make hypochlorite (NaClO).

₂ NaOH + Cl _{2 -} > NaCl + NaClO + H ₂ O

 In the case of such MGPS, hypochlorite is formed through the electrolysis reaction, thereby preventing proliferation and adhesion of marine organisms. Therefore, it is possible to effectively operate only when the concentration of the salt in the seawater is maintained at a proper level or higher.

However, when the ship is anchored near the land for a long time, the concentration of the salt contained in the seawater flowing into the cooling system installed in the ship may become significantly lower than the concentration of the salt contained in the seawater. In the case of a low salt water environment, the electrolysis reaction of the MGPS can not be effectively performed, thereby preventing the marine organisms from adhering to the pipeline and clogging the pipelines.

Open Patent No. 2010-0043876 (disclosed on Apr. 29, 2010)

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above-mentioned problems of the related art in that, when a ship is anchored near a land for a long time (that is, when the ship is exposed to a low-salt sea water environment) Which is a device for preventing the propagation of marine organisms contained in the seawater due to the concentration of the salt contained therein being lower than that of the salt contained in ordinary seawater. When the salt is exposed to the seawater environment, it is introduced into the MGPS without discharging seawater having high salinity discharged from the water purifier.

When the concentration of the salt contained in the seawater discharged from the water generator is not sufficiently high, the seawater discharged from the water generator is not discharged to the outside of the ship, but is recycled to the recycle tank, Which is capable of supplying seawater having a salt concentration of a predetermined level or higher to the MGPS, in a low-salt sea water environment.

Providing a method of effectively preventing the propagation of marine life even when the ship is exposed to the low salt and seawater environment by supplying seawater of high salinity generated by producing the fresh water from such a water tank to the apparatus for preventing attachment of marine life can do.

In order to solve the above-mentioned problems, the apparatus for preventing marine organism attachment which can be used in the low salt water environment proposed in the present invention is characterized in that seawater is supplied from a sea chest to a fresh water generator Seawater supply pump; A water purifier for treating the seawater supplied through the seawater supply pump and separating the seawater into fresh water (low-salt water) and high salt water; A salinity measuring sensor for measuring the salinity of the highly saline water discharged from the water purifier; A 3-way valve that supplies the salinity measured by the salinity measuring sensor to a recirculation tank when the salinity of the high salt water is less than a set value, and supplies the salinity to a marine organism attachment prevention unit (MGPS) And a marine organism attachment preventive device (MGPS) unit for electrolyzing seawater having a salinity equal to or higher than a set value supplied through the 3-way valve.

The high salt water supplied to the recycle tank is supplied again to the fresh water generator through the seawater supply pump, and the fresh water (low salt water) discharged through the fresh water generator can be discharged to the sea or stored in the fresh water storage tank.

Preferably, the fresh water generator is a low pressure distillation type scrubber capable of separating and producing fresh water from seawater through hot water supply in a reduced pressure state, or a reverse osmosis type fresh water generator including an reverse osmosis membrane filter.

The marine organism attachment preventive device (MGPS) unit mixes seawater having a salinity equal to or higher than a set value supplied through the 3-way valve with sterilizing material so as to be changed into sterilizing water. To this end, And an electrolytic device for decomposing to produce a sterilizing material.

According to another embodiment of the present invention, there is provided a method for preventing attachment of marine life usable in a low-salt sea water environment, the method comprising: supplying seawater from a sea chest to a fresh water generator; A fresh water treatment step of treating the seawater supplied in the seawater supply step and separating the seawater into fresh water (low salt water) and high salt water; A salinity measuring step of measuring salinity by using a salinity measuring sensor for high salinity water discharged from the fresh water treatment step; Supplying the saline solution to the recycle tank when the salinity measured by the salinity measuring sensor is less than the predetermined value and supplying the saline solution to the marine organism attachment preventing unit when the salinity is higher than the set value; And supplying seawater having a salinity equal to or greater than the set value to the marine organism attachment preventive device (MGPS) unit.

In order to prevent seawater from entering the apparatus or piping of the cooling system of the ship and to prevent the marine organisms in the seawater from adhering to the apparatus or the inside of the piping and causing the problem of blocking the pipe, electrochemistry prevents the marine products from sticking (MGPS), and it is essential to use seawater having a certain salt level or more in view of the characteristics of an MGPS device driven by an electrochemical method.

The apparatus for preventing the attachment of marine life usable in the low salinity sea water environment proposed in the present invention can effectively prevent the degradation of performance of the MGPS due to the supply of low salinity water which may occur when the ship is docked near the land for a long time And the salinity concentration of the seawater supplied to the MGPS is monitored periodically in accordance with the movement of the ship and the high salt generated in the water generator is selectively used for the MGPS through the control unit to maintain the performance of the MGPS constantly Respectively.

1 schematically shows a seawater supply line of a fresh water generator and an MGPS facility included in a conventional vessel.
FIG. 2 schematically shows an apparatus for preventing the attachment of marine life usable in the low salt water environment proposed in the present invention.
FIG. 3 is a photograph showing a result of adhesion of marine organisms due to degradation of MGPS when conventional MGPS operates in a low salt water environment.

Hereinafter, the technical features of the present invention will be described in detail with reference to embodiments and drawings. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims and their equivalents. shall.

FIG. 2 schematically shows concrete piping of a marine biofouling preventing device that can be used in the low salt marine environment proposed in the present invention.

The present invention will be described in detail in comparison with the conventional marine biofouling prevention device mentioned in FIG. Fresh water 31 can be discharged to the sea or stored in a fresh water storage tank in a water purifier 30 operated to produce fresh water in seawater.

Generally, about 80% of the seawater flowing into the fresh water generator is discharged as it is, and about 20% of the remaining seawater is evaporated in the form of fresh water, and the saline is separated to be produced in the form of fresh water (31). Therefore, for example, when the salinity concentration of the seawater introduced into the fresh water generator is about 3.4%, the salinity of the seawater discharged through the fresh water generator is about 4.25%, and the seawater 32 discharged by the amount of salinity contained in the produced fresh water, The salinity concentration of the water is increased.

Therefore, when the ship sails in a sea of normal high saltiness, the marine organism attachment preventive device 11 of the present invention is operated by the highly salted seawater 1 directly supplied to the MGPS 20. At this time, the concentration of the seawater supplied to the MGPS 20 is continuously measured by the salt concentration measuring device 77, and the result is transmitted to the control unit 70 in real time. In addition, the high salt water of the water generator 30 is discharged to the outside of the ship or the sea via the salt concentration measuring device 75 (direction (A)).

However, when the ship moves to the vicinity of the land and is moored for a long time, the salinity of the seawater supplied to the MGPS 20 is reduced, and the result measured by the salinity- The control unit 70 closes the valve 78 to block the low salt water from being supplied to the MGPS 20.

After the low-salt water supply is shut off, the concentration of the high salt water discharged from the water generator 30 is measured by the salt concentration measuring device 75. When the measured salt concentration is above a certain level (for example, about 3%), the control unit 70 controls the 3-way valve 76 so that the high-concentration brine discharged from the water generator 30 is supplied to the MGPS ((C) direction).

When the concentration of salt contained in the seawater is too low and the salt concentration of the high salt water discharged through the water generator 30 is too low (that is, the salt concentration measured by the salt concentration measuring device 75 is 3% The control unit 70 controls the 3-way valve 76 to deliver the brine discharged to the recycle tank 60 and opens the valve 80 in the control unit 70, And then supplied to the water purifier 30 through the pump 40 (direction (B)).

When the ship stays in a sea area having a low salt concentration, instead of supplying the sea water 1 to the MGPS 20, the high salt water discharged from the water generator 30 is supplied to the MGPS 20. If the concentration of high salt water discharged from the water generator 30 does not satisfy the salt concentration suitable for use in the MGPS 20, the water is supplied to the water generator 30 again via the recycle tank 60 By passing through the recirculation loop, circulation operation can be performed so that the concentration of the salt can be further increased.

When the ship is moored for a long time in the sea area near the land without using the apparatus for preventing attachment of marine life usable in the low salt water environment of the present invention, the MGPS system can not operate effectively due to the low salt concentration, As shown in Fig. 3, marine organisms may block pipelines.

The manipulator 30 which can be used in the present invention is not particularly limited, but a reverse osmosis regulator including a low-pressure distiller or membrane filter can be used.

In the case of the low-pressure distillation type water purifier, the cooling water is connected to the water jacket of the main engine of the ship so as to circulate the cooling water through the cooling water supply pipe and the cooling water return pipe,

The condensate circulation duct is branched from the cooling water return duct and communicably connected to a cascade tank. The cascade tank is communicatively connected to the auxiliary boiler through a fresh water circulation duct, Pump to the auxiliary boiler.

The auxiliary boiler is connected to the injector through a steam supply line, and the injector can supply steam to the fresh water generator through the cooling water supply line. At this time, the injector may be connected to an external fresh water supply line for adjusting the temperature of steam supplied to the fresh water generator, and may be separately connected to the condensate circulation line.

In addition, the auxiliary boiler supplies steam to a heater or tank requiring steam through a separate steam supply line, and the condensed water is recovered to the cascade tank through the recovery duct and circulated through the fresh water circulation duct . At this time, the fresh water generator makes the interior of the low pressure state, and the fresh water is produced by supplying a proper heat source while holding the seawater therein.

In the case of the reverse osmosis type water purifier, a pretreatment filter and a cartridge filter, a high-pressure pump for supplying the pretreated seawater to high pressure, and a reverse osmosis membrane filter for producing fresh water by treating the sea water supplied through the high- A plurality of built-in membrane cylinders, and a fresh water storage tank for storing fresh water produced through the membrane cylinders. In this case, the membrane cylinder is provided with only a single reverse osmosis membrane filter in each cylinder in the purification path between the high-pressure pump and the fresh water storage tank, and arranges the plurality of membrane cylinders in a parallel arrangement.

The marine organism growth inhibitor (MGPS) used in the present invention is not particularly limited, but an example of an electro-anode type that supplies ions to prevent the growth of marine organisms may be used. In this case, current is supplied to both electrodes of copper (Cu) and aluminum (Al) to release copper ions from the copper rod to prevent the growth of marine organisms, while aluminum hydroxide (AlOH3) It is possible to prevent the growth and corrosion of marine organisms by forming a thin film in the sea water supply line and inside the apparatus to which sea water is supplied.

As another example, in the case of a type that supplies chemicals to prevent the growth of marine life, chlorine is supplied to the sea water supply line as a chemical, thereby supplying chlorine by the flow of seawater to inhibit the growth of marine life.

Another embodiment of the present invention is a method for preventing attachment of a marine life using an apparatus for preventing attachment of a marine life usable in the low salt sea water environment shown in FIG. 2, wherein a sea water is introduced from a sea chest, fresh water generator); A fresh water treatment step of treating the seawater supplied in the seawater supply step and separating the seawater into fresh water (low salt water) and high salt water; A salinity measuring step of measuring salinity by using a salinity measuring sensor for high salinity water discharged from the fresh water treatment step; Supplying the saline solution to the recycle tank when the salinity measured by the salinity measuring sensor is less than the predetermined value and supplying the saline solution to the marine organism attachment preventing unit when the salinity is higher than the set value; And supplying seawater having a salinity equal to or greater than the set value to the marine organism attachment preventive device (MGPS) unit.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be construed as limited to the particular details of the embodiments set forth herein. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the present invention as defined by the appended claims.

1: High salt water 10: Conventional sea water supply system
11: The apparatus for preventing marine biofouling according to the present invention
20, 33, 34: Marine Life Protection System (MGPS)
30: fresh water 31: fresh water
32: Sea water discharge 40: Sea water supply pump
50: Chestch 60: Recirculation tank
70: control unit 75, 77: salinity concentration measuring device
76: 3-way valve 78, 80: valve

Claims (12)

A seawater supply pump for introducing seawater from a sea chest to a fresh water generator;
A water purifier for treating the seawater supplied through the seawater supply pump and separating the seawater into fresh water (low-salt water) and high salt water;
A salinity measuring sensor for measuring the salinity of the highly saline water discharged from the water purifier;
A 3-way valve that supplies the salinity measured by the salinity measuring sensor to a recirculation tank when the salinity of the high salt water is less than a set value, and supplies the salinity to a marine organism attachment prevention unit (MGPS) And
And a marine organism attachment preventive device (MGPS) unit for electrolyzing seawater having a salinity equal to or higher than the set value supplied through the 3-way valve. The method according to claim 1,
Characterized in that the high salt water supplied to the recycle tank is supplied back to the fresh water generator through the seawater supply pump. The method according to claim 1,
Wherein the fresh water discharged through the fresh water generator is discharged to the sea or stored in a fresh water storage tank. The method according to claim 1,
Wherein the fresh water generator is a low pressure distillation type fresh water generator capable of separating and producing fresh water from seawater through hot water supply in a reduced pressure state. The method according to claim 1,
Wherein the fresh water generator is a reverse osmosis type fresh water generator including a reverse osmosis membrane filter, wherein the fresh water generator can be used in a low salt water environment. The method according to claim 1,
The marine organism attachment preventive device (MGPS) unit electrolyzes a part of the supplied seawater in order to mix seawater having a salinity of more than a set value supplied through the 3-way valve with the germicidal material so as to be changed into sterilized water Characterized in that it comprises an electrolytic device for producing the germicidal material. In a method for preventing attachment of marine life usable in low salt water environment,
A seawater supply step of supplying seawater from a sea chest to a fresh water generator;
A fresh water treatment step of treating the seawater supplied in the seawater supply step and separating the seawater into fresh water (low salt water) and high salt water;
A salinity measuring step of measuring salinity by using a salinity measuring sensor for high salinity water discharged from the fresh water treatment step;
Supplying the saline solution to the recycle tank when the salinity measured by the salinity measuring sensor is less than the predetermined value and supplying the saline solution to the marine organism attachment preventing unit when the salinity is higher than the set value; And
And supplying seawater having a salinity greater than a predetermined value to a marine organism attachment preventive device (MGPS) unit. 8. The method of claim 7,
Characterized in that the high salt water supplied to the recycle tank is fed back to the fresh water generator through the seawater supply pump. 8. The method of claim 7,
Wherein the fresh water discharged through the fresh water generator is discharged to the sea or stored in a fresh water storage tank. 8. The method of claim 7,
Wherein the fresh water generator is a low pressure distillation type fresh water generator capable of separating and producing fresh water from seawater through hot water supply in a reduced pressure state. 8. The method of claim 7,
Characterized in that the fresh water generator is a reverse osmosis type fresh water generator including an reverse osmosis membrane filter. 8. The method of claim 7,
The marine organism attachment preventive device (MGPS) unit electrolyzes a part of the supplied seawater in order to mix seawater having a salinity of more than a set value supplied through the 3-way valve with the germicidal material so as to be changed into sterilized water Characterized in that it comprises an electrolytic device for producing said germicidal material.

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