KR101147924B1 - Apparatus for ship ballast water using electrolysis - Google Patents

Abstract

The present invention relates to an electrolytic disinfection apparatus for ballast water installed in a ship.
The present invention disclosed is a reaction tank having a flange extending outwardly at both ends and a pair of guide grooves opposed to each other are formed on the inner circumferential surface and coupled in the same line to the ballast pipe; A hydraulic pressure interrupting plate having at least two guide parts protruding in the flow direction of the ballast water at opposite sides of the mutually opposite sides, and fitted in a sliding manner along the guide groove of the reaction tank, and having a plurality of through-holes standing upright with respect to the flow direction of the ballast water. ; And a slender anode wire and a cathode wire having an annular shape as a whole so as to be wound in parallel with each other at regular intervals, and sliding along the guide groove of the reactor such that the parallel wound anode wire and the cathode wire are orthogonal to the flow direction of the ballast water. It includes an electrode module that is fitted in a manner to stand up.
As described above, the vessel which does not have the ballast water treatment apparatus has an advantage of simply installing the ballast water treatment apparatus without discharging the installation space or changing the design of the equipment to discharge clean ballast treated water.

Description

Apparatus for ship ballast water using electrolysis

The present invention relates to an apparatus for disinfecting ballast water for ships, such as cargo ships, passenger ships, and passenger ships. More specifically, the present invention relates to a ship which does not have a ballast water treatment device. To instantly disinfect aquatic organisms and bacteria in the seawater flowing into the ballast tank by electrochemical reaction, and maximize the contact area with ballast water during electrochemical reaction inside the reactor to maximize the treatment efficiency of disinfection. The present invention relates to an electrolytic disinfection apparatus for ballast water.

In general, ballast tanks are installed in cargo ships for transporting crude oil, containers, gas, LNG, etc., or ships such as passenger ships, ships, etc. to maintain the stability of the hull during navigation. Normally, when oil, container, and gas are not loaded, the ballast tank is filled with ballast water, and when the oil, container, and gas are loaded, the ballast water in the ballast tank is discharged, and the buoyancy of the hull is discharged. By adjusting, the performance of the ship is stabilized along with the balance of the hull.

Such ballast water is used for safe navigation of a ship, and seawater is normally used for harbors for unloading.

By the way, in the ballast water discharged | emitted from a ship, the aquatic organisms and microorganisms which reproduce in the harbor in which it was taken in are mixed. Since these aquatic organisms and bacteria are transferred to foreign countries by the movement of ships, aquatic organisms that were not originally reproduced in the sea area, instead of the existing aquatic organisms, cause disturbances of marine ecosystems. The destruction of indigenous ecosystems is getting serious.

Against this backdrop, treaties for the regulation and management of ballast water and sediment of ships have been adopted by the International Maritime Organization (IMO) of the Ministry of International Maritime Organization (IMO). Due to this, ships are required to discharge clean ballast water in which aquatic organisms or bacteria are killed to satisfy the above treaty conditions.

According to the above-mentioned discharge standard of ballast water according to the treaty of the International Maritime Organization (IMO), when the size of aquatic organisms is 10-50 μm, the number of viable organisms is 10 / ml and the size of the aquatic organisms is 50 μm. In this case, the number of viable organisms is 10 / m 3, and as indicator bacteria, E. coli is 250cfu / 100ml, Pathogenic cholera bacteria 1cfu / 100ml, Enterococci 100cfu / 100ml. It is decided.

In order for a ship to discharge clean ballast water that satisfies the conditions of the International Maritime Organization (IMO), a treatment device capable of sterilizing aquatic organisms and bacteria in the ballast water to be below a predetermined value is installed in the ship and the ballast at the time of intake. A method of performing a number treatment is considered.

Regarding the ballast water treatment apparatus, researches for treating the ballast water by physical, chemical, and electrical methods such as ozone method, ultraviolet ray method, and high temperature treatment method using heat disinfection in the US, Europe, and various Asian countries Has been actively promoted and commercialized, for example, Japanese Patent Laid-Open No. 2004-160437, Japanese Patent Laid-Open No. 2003-200156, Korean Laid-Open Patent Publication No. 2005-100092, Korean Laid-Open Patent Publication No. 2002-39265, and US Patent No. The specification 6125778 discloses known methods for the treatment of ballast water.

However, it is difficult to secure a space in which a vessel which has already been constructed is provided with the above treatment apparatus therein. Treatment of ballast water using a treatment apparatus is usually performed in the process of pouring or draining the ballast water. Since the water supply and drainage of the ballast water is carried out only at the time of arrival or departure, the treatment device operates only at the time of arrival or departure, so the actual operation period of the treatment device is only a very short period. Therefore, securing a space for newly installing the ballast water treatment device inside the ship, and further repairing, requires more manpower, time, and cost than the actual operating time of the device. There is a burden.

In the above prior arts, in Korean Patent Laid-Open Publication No. 2002-39265 (water electrolytic sterilization method and electrolytic sterilization apparatus), the target water is disinfected by putting it in water to disinfect hypochlorous acid contained in the electrolyzed water. This technology is characterized in that the treatment target and the sterilized water is separated, the hypochlorous acid and radicals contained in the sterilized water after the electrolysis process is put into the treatment target water to disinfect them. Since radicals have a very short lifespan, not only they decompose before reaching the target water, but also do not take advantage of the disinfection effect due to the potential difference formed near the electrode surface.

In Korean Patent Laid-Open Publication No. 2005-100092 (an ozone group in which an electrolysis generating core is connected in parallel), the platinum wire of the positive electrode and the platinum wire of the negative electrode are wound on the frame of the electrolytic generating core in the same direction so as to face each other. In this case, the ozone generation efficiency is improved by maximizing the opposing contact area with water during electrolysis. However, such a technique can be disinfected by electrolysis only when the amount of water to be treated is low. The flow rate of the water to be treated is enormous, and the efficiency of treatment of the ballast water which is desired to be sterilized momentarily is greatly reduced, and in the conventional case, the situation described above does not provide a specific countermeasure against this problem.

Therefore, the present invention was devised under the above-mentioned background, and an object of the present invention is to simply install the vessel without a ballast water treatment device without securing the installation space or changing the design of the device, thereby killing aquatic organisms and bacteria. It is to provide an electrolytic disinfection apparatus of ballast water to supply and discharge the clean ballast treated water to the ballast tank, which has the same or similar diameter as the pipe of the ballast tank, and has a thin anode wire inside. This is achieved by coupling the reactor with the electrode modules wound parallel to each other with the cathode rays spaced apart in the same line.

Another object of the present invention is to aquatic organisms due to the generation of ozone, hypochlorous acid and potential difference by passing the ballast water directly to the electrode module of the reaction tank irrespective of the water pressure, flow rate and flow rate of the ballast water flowing into the ballast tank And it provides an electrolytic disinfection device of ballast water to be able to instantaneously disinfect bacteria, this disinfection device is standing vertically at regular intervals in the reaction tank in the direction of the flow of the ballast water, water This is achieved by maximizing the contact area with.

Another object of the present invention is the electrode module installed inside the reaction vessel according to the amount of water to be treated (for example, the water of the vessel, the disinfectant wash water of a vessel, a container or the like, the home or the catering industry) and the amount of water to be treated. It is to provide an electrolytic disinfection apparatus of ballast water freely increase or decrease, and this disinfection apparatus forms a pair of guide grooves to face each other in the longitudinal direction of the reaction tank, and the desired number of electrode modules along the guide grooves. Achieved by sliding in or out of it in a sliding manner.

Other objects of the present invention will become more apparent from the following detailed description and the accompanying drawings.

According to the electrolytic disinfection device of the ballast water according to the present invention for achieving the above object, in the ballast water treatment apparatus for disinfecting the ballast water flowing into the ballast pipe of the ship by electrolysis to supply to the ballast tank;

A cylindrical reactor having a flange extending outwardly at both ends and having a pair of guide grooves formed opposite to each other from one end to the vicinity of the other end thereof in a longitudinal direction, the cylindrical reactor being coupled in line with the ballast pipe;

A disk having a plurality of apertures, the guide member protruding in the flow direction of the ballast water at least at the edges on both sides facing each other and is fitted in a sliding manner along the guide groove of the reactor to be perpendicular to the flow direction of the ballast water. At least one hydraulic interruption plate installed so as to stand upright; And

The anode and cathode lines have an annular shape as a whole so that they can be wound in parallel with each other at a predetermined interval therebetween, and the anode and cathode wires wound in parallel are orthogonal to the flow direction of the ballast water. It is characterized in that it comprises at least one electrode module that is fitted in a sliding manner along the guide groove is installed standing up between the hydraulic pressure control plate.

Optionally, the electrode module has an annular cross-sectional shape having a predetermined width, and the winding grooves are wound at regular intervals along the arc direction so that any one of the anode line and the cathode line can be wound on the front and rear surfaces facing each other. A winding table provided on the central outer circumferential surfaces of the left and right sides and provided with a pair of coupling holes spaced apart from each other;

Protrudingly formed between the coupling hole of the winding stand so as to be parallel to the flow direction of the ballast water is inserted along the guide groove of the reaction tank, when the winding stand is installed standing in the reaction vessel, to maintain a predetermined interval with the hydraulic pressure interrupting plate A spacing member for giving; And

Semi-circular arc type wider than the width of the winding table, winding grooves are provided at predetermined intervals along the arc direction so that the other polar wires can be wound in parallel with the wound polar wires at the front and rear facing each other. A pair of engaging projections are provided on inner surfaces of the left and right ends, respectively, and include first and second winding covers which are tightly coupled on the outer circumferential surface of the winding table with the gap maintaining member therebetween.

Optionally, the windings have the same width and are horizontally formed at the center of the inner circumferential surface of the winding table so as to be orthogonal to the wound poles, and the first and second winding grooves are formed at predetermined intervals along the longitudinal direction on the front and rear surfaces thereof. It further comprises a first auxiliary winding member for holding the poles of the poles so as not to flow loosely or left, right by the flow rate and water pressure of the water.

Optionally, the second auxiliary winding groove has the same length as the first auxiliary winding member, and a second auxiliary winding groove is formed at predetermined intervals along the longitudinal direction at the front and rear surfaces thereof, and is coupled to the first auxiliary winding member in parallel with the first auxiliary winding member. And second and third auxiliary winding members which hold the gaps of the second winding cover so that they do not flow loosely or left and right by the flow velocity of the water and the water pressure, and maintain a predetermined interval so that they do not come into contact with the poles of the winding table. Characterized in that further comprises.

Optionally, a binding groove is formed along the arc direction on the outer circumferential surface of the center in the width direction of the winding table and the first and second winding covers, respectively, and the polar line wound on the winding table and the first and second winding covers. It characterized in that it further comprises an annular first, second elastic ring having one end portion which is inserted with the elastic force in the binding groove so as to be in contact with each other and connected in parallel.

Optionally, the sum of the widths of the first to third auxiliary winding members may be the same as the width of the first and second winding covers.

In this way, by combining the reaction vessel having the electrode module wound around the anode line and the cathode line in the same line with the ballast pipe, it is necessary to secure the installation space of the disinfection treatment device for the existing ship which does not have the ballast water treatment device. Also, the electrodes wound on the electrode module are orthogonal to the ballast water to maximize the contact area, so that the efficiency of electrolysis is high, whereby the aquatic organisms remaining in the ballast water regardless of the water pressure, flow rate and flow rate of the ballast water. But there is an advantage that the bacteria are killed immediately.

According to the electrolytic disinfection apparatus of the ballast water of the present invention, a plurality of electrode modules made of thin anode wires and cathode wires wound inside the reactor having the same or similar diameter as the pipes of the ballast tanks are vertically stood at regular intervals. After the installation, the reactor can be connected to the ballast pipe in the same line using only the flange, so that the vessel can be easily installed without securing the installation space or changing the design of equipment for ships without a ballast water treatment device. .

In addition, regardless of the water pressure, flow rate, and flow rate of the ballast water, the ballast water is passed directly through the electrode module of the reaction tank to generate aquatic organisms and bacteria such as toxic vibrio collagena, Escherichia coli, etc. by ozone, hypochlorous acid generation and potential difference. Can be killed by

In addition, the area of the reaction tank and the electrode module can be increased or decreased depending on the number of water to be treated or the amount of water to be treated, so that it can be applied to disinfectant washing water of vessels, containers, etc., and general water treatment as well as contact with water. The large area has the effect of greatly improving the sterilization efficiency during electrolysis.

In addition, when designing a new ship, unlike other existing technologies in the limited and narrow space inside the ship when installing the device of the present invention that does not require a separate installation area has the advantage of maximizing space efficiency .

1 is a perspective view showing an exploded electrode module of the electrolytic sterilization apparatus of ballast water according to the present invention,
FIG. 2 is a perspective view illustrating a state in which a cathode wire is wound on a winding stand of the electrode module illustrated in FIG. 1 and the anode wire is connected in parallel without being separated by a first elastic ring.
3 is a perspective view illustrating a state in which the first and second winding covers and the second and third auxiliary winding members are coupled to the winding table of FIG. 2;
FIG. 4 is a perspective view illustrating a state in which a cathode ray is wound around the first and second winding covers and the second and third auxiliary winding members of FIG. 3, and the cathode ray is connected in parallel without leaving the second elastic ring.
5 is a perspective view showing the decomposition of the electrolytic disinfection apparatus of ballast water according to the present invention,
6 is a cross-sectional view showing the electrolytic disinfection apparatus of the ballast water of FIG.
7 is a cross-sectional view of a use state in which the electrolytic disinfection apparatus of the ballast water of FIG. 5 is coupled to a pipe of a ballast tank.

Hereinafter, with reference to the accompanying drawings a preferred embodiment of the electrolytic disinfection apparatus of ballast water according to the present invention will be described in detail.

As shown in Figs. 1 to 5, the electrolytic sterilization apparatus of the ballast water according to the present embodiment is largely provided with a reaction tank 10 having a constant diameter and length, and installed in the reaction tank 10 to adjust the water pressure and flow rate of the ballast water. It is composed of a combination of several electrode modules 30 which are installed between the several hydraulic pressure control plate 20 and the hydraulic control plate 20 in the reaction tank 10 to kill aquatic organisms or bacteria by electrolysis.

At this time, the reaction tank 10 satisfies the conditions of strength and resistance to strong water pressure, corrosion of seawater and oxidizing substances such as hypochlorous acid generated during electrolysis, and conditions of insulators that do not pass current. The material is embodied in a material such as polypropylene (PP), polyethylene (PE), polyvinyl chloride (PVC), and the like and is manufactured in a cylindrical shape. Of course, the shape of the reaction vessel 10 is not limited to the cylindrical shape, as in this embodiment, can be changed to a shape corresponding to various conditions, for example, the shape of the ballast pipe installed in the vessel.

Both end portions of the cylindrical reactor 10 are provided with a plurality of fasteners 12a and respective flanges 12 extending outwardly, and at the upper center, wire outlets for drawing wires connected to the electrode module 30. 12b is formed. In addition, a pair of guide grooves 14 and 16 are formed on the inner circumferential surface of the reaction tank 10 so as to face each other along the longitudinal direction from one end to the vicinity of the other end.

On the other hand, the plurality of hydraulic pressure control plate 20 and the plurality of electrode modules 30 as shown in Figs. 4 and 5 are alternately arranged at regular intervals, respectively, in the reaction tank 10 described above.

The hydraulic pressure interrupting plate 20 is, for example, implemented in the same material as the reaction vessel 10, it is manufactured in a disc shape. Here, the hydraulic interruption plate 20 may also be changed to a form corresponding to the reactor 10.

These disk-shaped hydraulic interrupting plate 20, as shown in Fig. 5, a plurality of through holes 26 are densely arranged, and guide grooves 14 and 16 of the reaction tank 10 at both edges thereof facing left and right. A pair of guide members 22 and 24 are provided to protrude in the flow direction of the ballast water so as to be inserted in a sliding manner.

As such, the guide members 22 and 24 are inserted into the guide grooves 14 and 16 of the reaction tank 10 in a sliding manner, so that the hydraulic pressure interrupting plate 20 stands in the reaction tank 10. By dispersing and controlling the water pressure or flow rate of the ballast water drawn into the reaction tank 10 in a state standing upright with respect to the flow direction of the ballast water through the through holes 26, it is installed at the rear end of the hydraulic pressure control plate 20. The influence on the electrode module 30 is minimized.

On the other hand, the above-described plurality of electrode modules 30, the winding table 32, the first, the second winding cover 42, 44, the second, the third auxiliary winding member 52, 54, the third Aquatic organisms remaining in the ballast water by electrolysis in the reaction vessel 10, which will be composed of a combination of the first and second elastic rings 40 and 50, the thin cathode ray 62 and the anode ray 60, which will be described later in detail. And kill bacteria.

The winding table 32 of the electrode module 30 is made of, for example, the same material as the reactor 10 and has an annular cross-sectional shape having a predetermined width. Of course, this winding 32 may also be changed to a form corresponding to the reactor (10).

As shown in FIG. 1, the annular cross-section winding table 32 has a sawtooth shape along the arc direction so as to wind a slender anode wire 60 made of a predetermined material, for example, platinum, on its front and rear surfaces facing each other. The winding grooves 32a are arranged at equal intervals, and the binding grooves 32c are formed along the circular arc direction on the center outer peripheral surface of the width direction.

In addition, the guide member 22 of the hydraulic pressure control plate 20 is inserted into the guide grooves 14 and 16 of the reaction tank 10 on the central outer peripheral surfaces of the left and right opposite sides of the winding stand 32, respectively. In contact with 24, the spacing members 34 and 36, which maintain a constant spacing with the hydraulic interrupting plates 20, protrude in parallel with the longitudinal direction of the reaction vessel 10, that is, the flow direction of the ballast water. And a pair of coupling holes 32b spaced apart from each other with a binding groove 32c interposed between upper and lower surfaces of the outer circumferential surface adjacent to the space keeping members 34 and 36.

 Moreover, the 1st auxiliary winding member 38 is horizontally provided in the form which divided the annular space part in the center of the inner peripheral surface of the winding stand 32. As shown in FIG. Here, it is preferable to make the 1st auxiliary winding member 38 the same as the width | variety of the winding stand 32. FIG. In addition, the front and rear surfaces of the first auxiliary winding member 38 are formed with tooth-shaped auxiliary winding grooves 38a which face each other with the winding grooves 32a of the winding table 32. In the portion where the winding groove 38a is not formed, auxiliary coupling holes 38b and 38c are formed so that the second and third auxiliary winding members 52 and 54 may be coupled to each other.

In the annular winding table 32 having such a structure, first, a thin platinum wire 60 is wound up. At this time, as shown in FIG. 2, the anode wire 60 may be vertically gripped while being spaced apart from each other. When the winding is continuously wound along the winding grooves from the winding groove 32a on one side to the winding groove on the other side, the anode wire 60 is also fitted to the auxiliary winding groove 38a of the first auxiliary winding member 38 to stabilize the winding. This is to prevent the sagging of the ballast flowing into the reaction vessel 10 during electrolysis, or the sagging of the anode wire 60 due to the water pressure and the flow rate is prevented from flowing to the left and right.

In addition, the first elastic ring 40 made of a conductor is inserted into the binding groove 32c of the winding table 32 in which the anode wires 60 are spaced apart from each other, and the anode wires 60 are connected to each other so that the anode wires 60 cross each other. 60 are electrically connected in parallel by the first elastic ring 40.

Meanwhile, the first and second winding covers 42 and 44 described above are made of the same material as the reaction tank 10 and manufactured in a semicircular arc shape wider than the width of the winding table 32.

The first and second winding covers 42 and 44 are sawtooth-shaped along the arc direction so as to wind a thin cathode ray 62 made of a predetermined material, such as platinum, on at least the front and rear surfaces thereof facing each other. The winding grooves 42a and 44a are formed in a continuous array at predetermined intervals, and binding grooves 42b and 44b are formed along the circular arc direction on the center outer peripheral surface of the width direction.

In addition, a pair of engaging projections 46 and 48 are formed on the inner surfaces of the left and right ends of the first and second winding covers 42 and 44, respectively, to maintain the gap maintaining member 34 of the winding table 32. It is forcibly fitted into the coupling hole 32b of the winding table 32 with the gap 36 therebetween, as shown in FIG.

In addition, the second and third auxiliary winding members 52 and 54 described above are made of the same material as the reactor 10 and have the same length as the first auxiliary winding member 38.

And before and after the second and third auxiliary winding members 52 and 54, the auxiliary winding grooves 38a of the first auxiliary winding members 38, and the first and second winding covers 42 and 44, respectively. Serrated auxiliary winding grooves 52a and 54a facing each other with the winding grooves 42a and 44a are formed along the longitudinal direction, respectively, and projections 52b and 54b are formed at both ends of the longitudinal direction, respectively. The coupling is made by forcing the auxiliary coupling holes 38b and 38c of the first auxiliary winding member 38. Here, the sum of the widths of the first to third auxiliary winding members 38, 52 and 54 and the widths of the first and second winding covers 42 and 44 are the same.

The first and second winding covers 42 and 44 coupled to the winding table 32 are wound with thin cathode rays 62 of platinum. At this time, as shown in FIG. Winding grooves 42a and 44a on one side to winding grooves on the other side are continuously wound along the winding grooves so as to be vertically picked up in the spaced apart state, such that the cathode ray 62 and the anode line 60 are spaced at regular intervals. It is made in parallel in the state, and also fits in the winding grooves 52a and 54a of the 2nd and 3rd auxiliary winding members 52 and 54, and stabilization of winding is maintained. Therefore, the two poles due to the fluctuation of the ballast water flowing into the reaction tank 10 by the first to third auxiliary winding members 38, 52, 54, water pressure, and flow rate are loosely stretched or left, right when electrolysis is performed. Not only prevents the flow, but also enables stable electrolysis without electrical contact with each other.

In addition, the second elastic ring 50 made of a conductor is formed in the binding grooves 42b and 44b of the first and second winding covers 42 and 44 on which the cathode ray 62 is wound. By interposing and connecting the cathode ray 62 with each other, the cathode rays 62 are electrically connected in parallel by the elastic force of the second elastic ring 50.

On the other hand, the plurality of pressure interruption plate 20 and the plurality of electrode modules 30 made as described above are installed standing up in the reaction vessel 10 as described above. In this case, the plurality of electrode modules 30 maintain a constant interval with the hydraulic interruption plate 20 by the contact between the space maintaining members 34 and 36 and the guide members 22 and 24 as shown in FIGS. 5 and 6. They are standing up and installed between them, whereby the anode wire 60 and the cathode ray 62 make contact with orthogonal to the ballast water which is seawater.

Then, the first and second elastic rings 50, 60 of the one electrode module 30 is connected to the wire (not shown in the drawing) and then connected again in parallel with a plurality of electrode modules reactor 10 To the wire lead-out port 12b. Electrolytic disinfecting apparatus of the present invention having such a structure is a sealing material such as O-ring, gasket to prevent the leakage of ballast water and disinfection water between the flange 12 of the reactor 10 and the flange of the ballast pipe 64 as shown in FIG. It is possible by fastening the ballast pipe 64 and the reaction tank 10 of the present invention in the same line with the bolt 68 through the (66).

In this state, when the power is applied to the electrode module 30 of the reaction tank 10 through the wiring discharged through the wiring outlet 12b, the ballast water, which is seawater, is electrolyzed, in which case the through hole 26 of the hydraulic pressure control plate 20 is provided. The sodium chloride (Nacl) component in the ballast water whose water pressure is lowered and the flow rate is lowered through the electrolysis is replaced with hypochlorite ions (OCL ^_ , HClO), and thus, the anode line 60 and the cathode ray 62 of the electrode module 30. In addition to annihilating aquatic organisms and bacteria passing through them, in addition to electrolysis, OH-radicals, ozone (O ₃ ), H ₂ O _2, etc. are generated to act as sterilization and disinfection. When it flows, it decomposes naturally and is reduced to harmless water (H ₂ O) and oxygen (O ₂ ). In addition, due to the potential difference between the anode wire 60 and the cathode ray 62, aquatic organisms and bacteria remaining in the ballast water burst the cell membranes to instantly sterilize microorganisms such as bacteria. The ballast water sterilized in this way is discharged after being supplied to the ballast tank, thereby preventing marine pollution.

On the other hand, in a comparative example, in order to satisfy the conventional technology, that is, in other words, the conditions prescribed by the International Maritime Organization (IMO), a space for installing a ballast water treatment apparatus must be secured separately on a ship, and a treatment apparatus is installed. Unlike the installation cost increases with the increase in the number of working hours in the present invention, the present invention combines the reaction vessel provided with several hydraulic pressure control plates in the same line as the existing ballast pipe using only the flange, and disinfects the ballast water. It can be seen that.

According to the present invention, according to the present invention, a ballast water treatment apparatus can be easily installed for a vessel without a ballast water treatment apparatus without securing an installation space or changing the design of equipment, thereby removing clean water from the aquatic organisms and bacteria. There is an advantage to discharge.

In addition, although specific embodiments of the present invention have been described and illustrated above, it is obvious that the present invention may be variously modified and implemented by those skilled in the art.

Such modified embodiments should not be individually understood from the technical spirit or the prospect of the present invention, and such modified embodiments shall fall within the appended utility model registration claims of the present invention.

10: reactor 20: hydraulic pressure control plate
22: guide member 30: electrode module
32: winding table 34, 36: spacing member
38: first auxiliary winding member 40: first elastic ring
42, 44: first and second winding cover 46, 48: engaging projection
50: second elastic ring 52, 54: second, third auxiliary winding member
60: anode wire 62: cathode ray

Claims (6)

A ballast water treatment apparatus for disinfecting ballast water introduced into a ballast pipe of a ship by electrolysis to supply to a ballast tank;
(1) With respect to the longitudinal direction, a pair of guide grooves having flanges extending outwardly at both ends and opposed to each other from one end to the vicinity of the other end are formed on the inner circumferential surface thereof so as to be coupled in the same line to the ballast pipe. Reactor;
(2) a disk having a plurality of through holes, having at least two guide portions protruding in the flow direction of the ballast water at opposite edges thereof, and being fitted in a sliding manner along the guide grooves of the reaction tank to flow direction of the ballast water; At least one hydraulic interruption plate installed vertically standing with respect to the; And
(3) the slender anode wire and the cathode wire have an annular shape as a whole so as to be wound in parallel with each other at regular intervals, and the parallel wound anode wire and the cathode ray are perpendicular to the flow direction of the ballast water. Electrolytic disinfection device of the ballast water, characterized in that it comprises at least one electrode module fitted in the sliding manner along the guide groove of the reactor is installed between the hydraulic pressure control plate.
The method according to claim 1,
The electrode module,
An annular cross-sectional shape having a predetermined width, the winding grooves are provided at regular intervals along the arc direction so that any one of the anode line and the cathode line can be wound on the front and rear surfaces facing each other. A winding table provided on the outer circumferential surface with a pair of coupling holes spaced apart from each other and standing upright in the reactor;
Protrudingly formed between the coupling hole of the winding stand so as to be parallel to the flow direction of the ballast water is inserted along the guide groove of the reaction tank, when the winding stand is installed standing in the reaction vessel, to maintain a predetermined interval with the hydraulic pressure interrupting plate A spacing member for giving; And
Semi-circular arc type wider than the width of the winding table, winding grooves are provided at predetermined intervals along the arc direction so that the other polar wires can be wound in parallel with the wound polar wires at the front and rear facing each other. Electrolytic disinfection of ballast water, characterized in that the inner surface of the left and right ends are provided with a pair of engaging projections, respectively, the first and second winding covers tightly coupled on the outer circumferential surface of the winding table with the gap holding member therebetween. Device.
The method according to claim 2,
A binding groove is formed in an outer circumferential surface of the center in the width direction of the winding table and the first and second winding covers, respectively, in an arc direction, and intersects with the poles wound on the winding table and the first and second winding covers. And an annular first and second elastic rings having one end portion cut in close contact with the binding groove with elastic force to be connected in parallel to each other.
The method according to claim 2,
It has the same width as the winding table and is formed horizontally in the center of the inner circumferential surface of the winding table orthogonal to the wound poles, and the auxiliary winding grooves are formed at regular intervals along the longitudinal direction in the front and rear, so that the polar lines of the winding table are water flow rates. And Electrolytic disinfection apparatus of ballast water, characterized in that it further comprises a first auxiliary winding member for holding so as not to flow loosely or left, right by the water pressure
The method of claim 4,
The auxiliary winding groove has the same length as the first auxiliary winding member, and an auxiliary winding groove is formed at predetermined intervals along the longitudinal direction at the front and rear surfaces thereof, and is coupled in parallel to the first auxiliary winding member and the first and second winding covers. It further comprises a second and third auxiliary winding member for holding the poles of the poles so as not to come loose or left, right flow due to the flow rate and water pressure of the water and not to come in contact with the poles of the winding table. Electrolytic disinfection device of ballast water. The method according to claim 5,
The sum of the widths of the first to third auxiliary winding members is equal to the width of the first and second winding covers, characterized in that the ballast water electrolytic disinfection device.

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