KR101672354B1 - Electrolysis apparatus - Google Patents

Abstract

The present invention relates to an electrolytic apparatus. The electrolytic apparatus has a semi-cylindrical upper electrode, a lower electrode having the same size and the same shape as the upper electrode, a lower electrode located in contact with the upper electrode, a diameter larger than a length corresponding to the diameter of the upper electrode, A cylindrical pipe which is positioned to surround the outside of the upper electrode and the lower electrode, a groove which is inserted into the pipe in a direction crossing the pipe and has a size corresponding to the thickness of the upper electrode and the lower electrode, And a bus bar which is formed at both ends of the pipe and transfers a current received from the outside to the upper electrode and the lower electrode, The electrode and the lower electrode are positioned in a pipe shape when they are in contact with each other , The upper electrode and the lower electrode generates a disinfectant by electrolyzing the number of ballast water flowing in from the outside by receiving a current from directly above the booth. As a result, it is possible to include a plurality of electrodes, so that the efficiency of generating a high concentration of bactericide from the ballast water is good.

Description

[0001] ELECTROLYSIS APPARATUS [0002]

The present invention relates to a seawater electrolysis apparatus.

Vessels that receive ballast water from outside, store it and operate it are used to maintain the balance of the ship using ballast water.

The ballast water flowing into the ship is sterilized and neutralized and discharged. The sterilizing agent is produced in the process of sterilizing and electrolyzing the ballast water, and the sterilizing agent produced is used to kill the microorganisms contained in the ballast water .

At this time, the process of electrolyzing the ballast water to produce a sterilizing agent is performed in a ballast water management system (BWMS) installed in the ship, and all of the ballast water introduced into the pipeline of the ship ballast water treatment apparatus The electrolytic water is electrolyzed through electrolytic water passing through which the electrolytic water is passed and electrolytically taken or a part of the ballast water flowing into the piping of the ship ballast water treatment apparatus is electrolyzed to electrolyze the electrolytic water to produce hypochlorite, .

In this case, in order to electrolyze the ballast water through the full water passing method or the non-electrolytic water passing method, in case of the full water passing method, a plate-like electrode is inserted into the main pipe of the ballast water treatment apparatus, In the case of the non-electrolytic water passing method, a plate-like electrode is inserted into the branch pipe connected to the main pipe of the ship ballast water treatment apparatus to electrolyze the ballast water flowing into the branch pipe.

However, in this case, in the case of the non-electrolytic water passing method, it is not easy to provide a plate-like electrode in the branch pipe having a small diameter in comparison with the diameter of the main pipe. Even if the electrode is installed, The efficiency of electrolyzing the ballast water to produce bactericide was low.

In addition, during the electrolysis of the ballast water through the non-electric water passing method, the ballast water passes through the inside of the branch pipe at a flow rate of 0.3 m / sec or less, so that the contaminants contained in the ballast water are installed inside the branch pipe There is a disadvantage in that the electrolysis efficiency is lowered due to accumulation on the surface of the electrode or a negative electrode scale accumulated on the cathode in the electrode.

SUMMARY OF THE INVENTION The object of the present invention is to efficiently dispose a plurality of electrode units in a branch pipe to efficiently produce a disinfectant from ship equilibrium in a process of electrolyzing ship equilibrium water through a non- will be.

The electrode part, which is provided inside the branch pipe and has a pipe shape, is formed by positioning the semicylindrical electrodes, which are separated from each other in the longitudinal direction, so as to face each other, thereby easily coating the inside and outside of the semi-cylindrical electrode .

An electrolytic apparatus according to an embodiment of the present invention includes an upper electrode having a semi-cylindrical shape, a lower electrode having the same size and shape as the upper electrode, a lower electrode disposed in contact with the upper electrode, A cylindrical pipe having a diameter larger than a length of the upper electrode and the lower electrode and surrounding the upper electrode and the lower electrode, a cylindrical pipe inserted in the pipe in a direction crossing the pipe, A spacer formed on both ends of the pipe and having a groove formed in a corresponding size to interpose the upper electrode and the lower electrode in between the grooves and to transmit a current received from the outside to the upper electrode and the lower electrode, Wherein the upper electrode and the lower electrode comprise a bus bar, And a loop-like position, wherein the upper electrode and the lower electrode generates a disinfectant by electrolyzing the number of ballast water coming from outside by receiving a current from directly above the booth.

In one example, at least one other upper electrode sized to be inserted into the pipe and different in size from the upper electrode, and formed in the same size and shape as the at least one other upper electrode Further comprising at least one further lower electrode located in contact with said another upper electrode, said spacer further comprising a groove for fixing said at least one further upper electrode and said at least one further lower electrode It is good to do.

In the groove of the spacer, the periphery of the upper electrode and the lower electrode are fitted not at a point where the upper electrode contacts the lower electrode, and at least two spacers are formed to intersect each other in different directions.

According to another embodiment of the present invention, there is provided an electrolytic apparatus comprising: an upper electrode having a polygonal shape; a lower electrode having the same size and shape as the upper electrode and positioned in contact with the upper electrode; A pipe having a diameter larger than the length of the pipe and positioned to surround the outside of the upper electrode and the lower electrode, a pipe inserted in the pipe in a direction crossing the pipe, And a bus bar that is formed at both ends of the pipe and transmits a current received from the outside to the upper electrode and the lower electrode, And when the upper electrode and the lower electrode are in contact with each other, Located in the upper electrode and the lower electrode generates a disinfectant by electrolyzing the number of ballast water flowing in from the outside by receiving a current from directly above the booth.

In one example, the pipe in which the upper electrode and the lower electrode are formed in contact with each other may be a square, hexagonal, or octagonal pipe.

According to this aspect, the electrolytic apparatus of the present invention includes a pair of semicylindrical electrodes to form an electrode portion so as to have a pipe shape, and a plurality of electrode portions are provided inside the branch pipe of the ship ballast water treatment device, It is possible to efficiently produce the bactericide from the ballast water.

In addition, since the electrode is formed in a semi-cylindrical shape, the electrode can be easily manufactured, and the cost can be reduced, and the inside and the outside of the electrode can be easily coated.

1 is a view showing a first electrode of an electrolytic apparatus according to an embodiment of the present invention.
2 is a view showing a second electrode of the electrolytic apparatus according to an embodiment of the present invention.
3 is a view showing an electrode unit of an electrolytic apparatus according to an embodiment of the present invention.
4 is a view showing a coupling structure of an electrode part and a spacer of an electrolytic apparatus according to an embodiment of the present invention.
5 is a view showing an electrolytic apparatus according to an embodiment of the present invention.
6 is a side view showing the connection structure of the bus bar and the electrode in detail in the electrolytic apparatus according to an embodiment of the present invention.
7 is a view showing an electrolytic apparatus according to an embodiment of the present invention.
8 is a view showing a connection structure between an electrolytic apparatus and a rectifier according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In order to clearly explain the present invention in the drawings, parts not related to the description are omitted.

First, the structure of the electrolytic apparatus of the present invention will be described with reference to Figs. 1 to 8. Fig.

The electrolytic apparatus according to an embodiment of the present invention is an apparatus for electrolyzing ship ballast water introduced into a ship ballast water treatment apparatus, in which the ballast water flowing through branch pipelines connected to the main duct is electrolyzed Which is a non-aqueous electrolytic solution.

In one example, an electrolytic apparatus according to an embodiment of the present invention is connected to a part of a branch pipe connected to a main pipe of a marine ballast water treatment apparatus or to a branch pipe thereof for electrolyzing the marine ballast water into a non- May be formed as a module.

The electrolytic apparatus according to an embodiment of the present invention has a structure in which a plurality of electrode units each having a pair of electrodes are provided and a plurality of electrodes are fixed by a spacer to be fixed inside the pipe. It is formed into a cylindrical shape or a polygonal shape as shown in Fig.

Referring to FIG. 1, the structure of the electrode of the electrolytic apparatus according to the first embodiment of the present invention will be described. The first electrode 10 has a cylindrical shape having no bottom surface and no top surface, And has a cylindrical shape.

The first electrode 10 having a semicylindrical shape includes a convex outer surface 11 and an inner surface 12 concavedly formed. As shown in FIG. 1 (c), the first electrode 10 10 as a first upper electrode and a first lower electrode 20 having the same shape as the first electrode 10 is formed in a pipe shape so as to be in contact with the first electrode 10.

In this case, the first electrode 10, which is the first upper electrode, and the first lower electrode 20 are formed to have exactly the same shape. In one example, each of the portions, which are in contact with each other, .

However, in another example, the two semicylindrical tangents that are tangential may be placed in abutting contact with each other and fixed by an external fixture.

When the first electrode 10 is an anode, a metal oxide is coated on the semi-cylindrical body of the first electrode 10. The metal oxide may be a transition metal such as Pt, (Ir), ruthenium (Ru), palladium (Pd), titanium (Ti), decaluminum (Ta), tin (Sn) or antimony (Sb) salts.

The first electrode 10 coated with the above metal oxide is preferably subjected to thermosetting treatment.

As the first electrode 10, which is an anode formed of titanium material, is formed by coating with a transition metal and thermally plasticized, the inner surface 12 or the outer surface 12 of the first electrode 10, It is possible to prevent the surface of the substrate 11 from being oxidized (corroded).

In addition, there is an effect of preventing corrosion due to high concentration of bactericide generated by electrolysis of ship ballast water and preventing corrosion by leakage current.

When the first electrode 10 is a cathode, the first electrode 10 is formed of titanium or stainless steel, and a metal oxide, which is a transition metal, is not coated as in the case of the anode.

However, in order to prevent the surface of the first electrode 10, which is a cathode, from being oxidized when applying the inversion of the electrode, which is a method of electrolytically removing the scale generated on the surface of the first electrode 10 which is a cathode, The first electrode 10, which is a cathode, may be coated with a metal oxide as in the case of the anode.

In addition, since the first electrode 10 is formed to have a semi-cylindrical shape, the coating of the metal oxide on the first electrode 10 can be easily performed.

At this time, a distance from one end of the first electrode 10 to the other end, and a distance from one end to the other end in the side of FIG. 1 (b), that is, When the two electrodes 10, 20 are in contact with each other to form a pipe shape, the diameter of the pipe is set so that the flow velocity of the ballast water passing along the pipe-shaped inner surfaces 12, 22 is at least 0.3 m / sec It is preferable to set it to flow.

For example, as shown in FIG. 1 (c), the first electrode 10 and the first lower electrode 20, which are the first upper electrode, When the flow rate of the ballast water flowing along the inner surface 22 of the surface 12 and the second lower electrode 20 is 10 m 3 / hr, the diameter of the pipe is preferably set to 100 mm or less.

At this time, it is preferable to design the diameter of the pipe so that the ballast water penetrates the inside of the pipe at a flow rate of 0.3 m / sec or more, and prevent the scale from being generated in the negative electrode as the ballast water moves at a flow velocity of less than 0.3 m / sec .

In the above description, referring to FIG. 1, the first electrode according to the first embodiment, that is, the two first electrodes 10 as shown in FIG. 1 (c) The electrode according to the second embodiment may be formed of the second electrode 30 having a polygonal shape as shown in FIG.

Referring to FIG. 2, the structure of the electrode of the electrolytic apparatus according to the first embodiment will be described. The second electrode 30 is a half octagonal column in which an octagonal pillar shape having no bottom surface and no top surface is cut in half along the longitudinal direction. Shape.

The second electrode 30 having a semi-octagonal barrel shape includes a convex outer surface 31 and a concave inner surface 32, and as shown in FIG. 2 (c) The second lower electrode 40 having the same shape as that of the second electrode 30 is disposed so as to be in contact with the second electrode 30 as the second upper electrode so as to form an octagonal columnar shape .

In this case, the second upper electrode 30 and the second lower electrode 40 are formed to have the same shape, and as described above with reference to the first electrode 10, Each of the contacting portions can be fixed in an adhesive or welded form, or in an abutting form without additional bonding, and then fixed by an external fixing device.

2 (a) and 2 (b), the second electrode 30 is formed to have an octagonal columnar structure as shown in FIG. 2 (c) when the two second electrodes 30, In the preferred embodiment, the second electrode 30 has three surfaces adjacent to each other having the same area, and two of the three surfaces of the adjacent three surfaces having the same area And one face having an area of 1/2 of three faces is connected to each of the four faces.

In other words, the second electrode 30 is formed in a polygonal structure having five faces, and two faces respectively located on the edges of the faces constituting the second electrode 30 are three faces When the two second electrodes 30 and 40 are formed so as to be in contact with each other as shown in FIG. 2 (c), the respective edge surfaces are connected to each other to form the middle portion So that the eight planes constituting the octagonal column all have the same area.

In the same manner, the second electrode 30 connects the two second electrodes 30 and 40 to form an octagonal column, a hexagonal column, and a columnar shape having even-numbered surfaces such as a ten- (Half) of the column can be formed as the second electrode 30 in order to form the second electrode 30. However, as shown in FIG. 2, Manufacturing efficiency is the best.

As described with reference to FIG. 2, the second electrode 30 having a polygonal structure and having a polygonal columnar shape when the two electrodes are brought into contact with each other is a half-octagonal-shaped second electrode 30, There is an effect that the electrode 10 is easier to manufacture than the electrode 10.

The second electrode 30 is formed of the same material as that of the first electrode 10 described above with reference to FIG. 1, coated and thermally fired according to the anode and the cathode, The diameter is designed to flow.

As described above, the electrode according to the second embodiment may be formed of the second electrode 30 described with reference to FIG. 2. However, in the description of the electrolytic apparatus according to the embodiment of the present invention, In the embodiment of the present invention in which the first electrode 10 is formed as a reference and the first electrode 10 is formed, the first electrode 10 is replaced with the second electrode 30, It should be interpreted as context.

Therefore, the electrolytic apparatus according to one embodiment of the present invention will be described with reference to the first electrode 10 having the structure shown in FIG. 1. As shown in FIG. 3, Two first upper electrodes 10a and 10b and two first lower electrodes 20a and 20b or first electrode 10 are formed to form two pipes.

3 (a), the electrode unit 100 includes a pair of first electrodes 10a and 20a positioned to face each other, and the other pair of electrodes One electrode 10b and 20b are formed as one second pipe and are located outside the first pipe.

3 (b), which is a cross-sectional view taken along the line I-I 'of the electrode unit 100 formed by folding the first pipe and the second pipe, 100 includes a first upper electrode 10b including a first upper electrode 10a including an inner surface 12a and an outer surface 11a, an inner surface 12b and an outer surface 11b, A first lower electrode 20a including an outer surface 22a and an outer surface 21a and a first lower electrode 20b including an inner surface 22b and an outer surface 21b.

One first upper electrode 10a has a polarity opposite to that of the other first upper electrode 10b and one first lower electrode 20a has a polarity opposite to the other first lower electrode 20b Polarity.

One first upper electrode 10a and one first lower electrode 20a are formed to have the same size and the other one of the first upper electrode 10b and the other first lower electrode 20b And have respective pipe shapes when they are formed in the same size and are formed in contact with each other.

At this time, the diameters of the second pipes 10b and 20b, which are outer pipes, are larger than the diameters of the first pipes 10a and 20a which are inner pipes.

As such, the electrode unit 100 is provided with at least two pipes, and each of the pipes has different polarities.

The electrolytic apparatus includes a cylindrical pipe 1 having a diameter larger than the maximum diameter of the electrode unit 100 having a plurality of pipe shapes including a pair of first electrodes 10, And further includes spacers 2a and 2b for supporting the first electrodes 10 constituting the electrode unit 100. [

The first pipes 10a and 20a, the second pipes 10b and 20b, the third pipes 10c and 20c and the fourth pipes 10d and 20d are connected to the pipe 1 The spacers 2a and 2b are located inside the pipe 1 and have grooves through which the first to fourth pipes can be inserted to adjust the spacing of the first to fourth pipes.

The pipe 1 may be longer than the first to fourth pipes.

The spacers 2a and 2b are formed to have a length corresponding to the diameter of the first pipe 1 so that the first to fourth pipes sandwiched between the grooves of the spacers 2a and 2b are fixed The first to fourth pipes are respectively located at one end of the first to fourth pipes and at the other end of the first to fourth pipes so that the first to fourth pipes are supported by the pipe 1 ).

4 (a) and 4 (b), the first upper electrode and the first lower electrode constituting the first to fourth pipes are separated from each other. However, the first upper electrode and the first The first upper electrodes 10a, 10b, 10c, and 10d are disposed on the first lower side of the pipe 1 when the first to fourth pipes are positioned inside the pipe 1. In this case, 20b, 20c, and 20d.

The spacers 2a and 2b are located inside the pipe 1 and can be formed in plural as shown in Figure 4 and the diameter 26 of the spacer 2a is formed to have a length corresponding to the diameter of the pipe 1 Is placed across the diameter of the pipe (1).

In a preferred example, it is preferable that at least two spacers 2a and 2b are provided, and that the two spacers 2a and 2b are located in different directions. By way of example, the two spacers 2a, 2b may be positioned orthogonal to each other.

In another example, it may be formed as an X-shaped integral structure in which spacers 2a and 2b are formed in two directions.

At this time, the two spacers 2a and 2b are formed so that the first to fourth pipes 10a, 10b, 10c, and 10d contact the first lower electrodes 20a, 20b, 20c, and 20d So that the spacers 2a and 2b keep the first to fourth pipes respectively in a pipe shape and the gap 15 is maintained between the pipes.

Here, a gap 15 between the pipes generated by the spacers 2a and 2b, for example, a third pipe formed by the first upper electrode 10c and the first lower electrode 20c, The gap 15 between the fourth pipe formed by the first lower electrode 10d and the first lower electrode 20d is set such that the first lower electrode 20c and the first lower electrode 20d are inserted into the groove formed in the spacer 2a And the gap 15 generated between the two pipes is such that the velocity of the ballast water passing through the space generated by the gap generated between the fourth pipe and the third pipe is at least 0.3 m / sec In order to allow the flow of gas to flow.

In one example, the distance (15) between the third pipe and the fourth pipe, the diameter of the third pipe, and the equation of Q = AV (flow Q is proportional to cross-sectional area A and flow velocity V) It is preferable to design the interval of the grooves formed in the spacers 2a and 2b so that the interval 15 between the first pipe and the fourth pipe is appropriately designed.

Since the spacers 2a and 2b form the interval between the first to fourth pipes located inside the pipe 1, it is possible to prevent the occurrence of electrode short between the first to fourth pipes in which the positive electrode and the negative electrode are arranged in an intersecting manner can do.

4 (c), the spacers 2a and 2b are provided with grooves of a size 25 corresponding to the thicknesses 16 of the first to fourth pipes, 4 pipes are fitted so as to support the first to fourth pipes in the pipe 1. [

At this time, the spacers 2a and 2b may be formed of a nonconductive material or coated with such a nonconductive material.

Referring to FIG. 5, an electrolytic apparatus according to an embodiment of the present invention including a plurality of electrodes having a pipe shape and spacers 2a and 2b for maintaining an interval therebetween will be described with reference to FIG. 5 The electrode unit 100 and the spacers 2a and 2b are provided inside the pipe 1 and the first bus bar 110 and the second bus bar 110 are provided at both ends of the pipe 1, And two bus bars 120, respectively.

The first bus bar 110 connected to one end of the pipe 1 receives the current from the outside and is connected to the first upper electrodes 10a and 10b which are the electrode parts 100 located inside the pipe 1, To the first lower electrodes 20a and 20b.

A first flange 1100 is positioned between the first bus bar 110 and the pipe 1 and a gasket 1150 is provided between the first bus bar 110 and the first flange 1100. [ ).

The first flange 1100 is for connecting the first bus bar 110 to the pipe 1 and the gasket 1150 for buffering and insulating between the first flange 1100 and the first bus bar 110 .

The second bus bar 120 connected to the other end of the pipe 1 transfers the current received from the electrode unit 100 inside the pipe 1 to the adjacent booth bar, A second flange 1200 is positioned between the pipe 120 and the pipe 1.

At this time, a gasket 1250 is positioned between the second bus bar 120 and the second flange 1200.

The first bus bar 110 and the second bus bar 120 may have a shape that is opened to the first bus bar 110 and the second bus bar 120 so that the ballast water can pass through the inside of the pipe 1. [ A first bus bar protrusion 111 which is a protruding structure for connecting the first bus bar 110 and the second bus bar 120 to the adjacent bus bar and a second bus bar protrusion 111 which is a protruding structure for connecting the first bus bar 110 and the second bus bar 120 to the adjacent bus bar, And a bar protrusion 121.

The first bus bar protrusion 111 and the second bus bar protrusion 121 form the first electrode connection protrusion hole 112 and the second electrode connection protrusion hole 122 respectively and the first and second electrode connection protrusions 112, The projecting holes 112 and 122 are located side by side with the projecting holes formed in the adjoining bus bars.

At this time, due to the electrode connection part 150 (shown in FIG. 8) positioned through the first or second electrode connection protrusion holes 112 and 122, the first or second electrode connection part 150, Electrode connection protrusion holes 112 and 122 are electrically connected to each other.

In one example, the electrode connection part 150 is formed to be smaller than the hole size of the first or second electrode connection protrusion hole 112, 122 to penetrate the first or second electrode connection protrusion hole 112, 122 .

In another example, the first bus bar protrusion 111 and the second bus bar protrusion 121 may not form the first electrode connection protrusion hole 112 or the second electrode connection protrusion hole 122. At this time, the first electrode connection part 150 is formed as a clamp or a clip, and the first or second bus bar protrusion 111 or 121 is fixedly connected from the outside to connect the first bus bar protrusion 111 and the second bus bar protrusion 111. [ And two adjacent bus bars including the bus bars 121 may be electrically connected.

The electrode connection unit 150 may further include a bending structure for preventing the connection structure with the first or second bus bar protrusion 111 or 121 from being disassembled.

The electrode connection part 150 may further include an insulating part to maintain a state of being electrically insulated from the outside.

In an example of the electrolytic apparatus with reference to FIG. 5 (b), the first bus bar 110 is a booth carrying a negative current and the second bus bar 120 is a The first upper electrode 10a, the first lower electrode 20a, and the center cathode electrode 10 ', which are cathode electrodes among the electrodes located inside the pipe 1, are connected to the first bus bar 110, To the first bus bar connection part 110 'connected to the first bus bar connection part 110'.

The first upper electrode 10b and the first lower electrode 20b which are the anode electrodes among the electrodes located inside the pipe 1 are connected to the second bus bar connecting portion 120 'connected to the second bus bar 120 .

In this case, the first bus bar connecting portion 110 'is connected to the first bus bar 110 having a circular plate shape and positioned inside the pipe 1, And transfers the current to the contacted electrode.

The first bus bar connecting portion 110 'is located in contact with the side surface of the first upper electrode 10a and the end portion of the first lower electrode 20a and is located in contact with the end portion of the center cathode electrode 10'.

In one example, the first upper electrode 10a and the first lower electrode 20a, which are connected to the first bus bar connecting portion 110 ', may be fixedly connected to each other by using bolts and screws.

At this time, the center cathode electrode 10 'connected to the first bus bar connecting portion 110' may also be fixedly connected through bolts and screws.

The second bus bar connecting portion 120 'is connected to the second bus bar 120 in the shape of a circular disk and is located inside the pipe 1 and receives a positive electric current from the second bus bar 120, The current is delivered to the electrode.

The second bus bar connecting portion 120 'is located adjacent to one of the first and second upper electrode 10b and the first lower electrode 20b and is connected to the first upper electrode 10b through a bolt and a screw, And the first lower electrode 20b.

5B, a first pipe composed of a first upper electrode 10a and a first lower electrode 20a, and a second pipe formed of a first upper electrode 10b and a first lower electrode 20b. And a second pipe composed of the electrode 20b. In the embodiment of the present invention, the pipe 1 may further include a plurality of electrodes therein.

Referring to FIG. 5C, the electrode unit 100 includes a plurality of electrodes (not shown) disposed in the pipe 1. The electrode unit 100 includes a plurality of electrodes Upper electrodes 10a, 10b, 10c, and 10d, and first lower electrodes 20a, 20b, 20c, and 20d.

The two first upper electrodes 10a and 10c and the first lower electrodes 20a and 20c are located in contact with the first bus bar connecting portion 110 'and two first upper electrodes 10b and 10d, The electrodes 20b and 20d are located in contact with the second bus bar connecting portion 120 '.

That is, in FIG. 5 (c), a first pipe composed of the first upper electrode 10a and the first lower electrode 20a, and a second pipe composed of the first upper electrode 10c and the first lower electrode 20c The sides of each of the third pipes are located adjacent to the first bus bar connecting portion 110 'and are connected to the first bus bar connecting portion 110' through bolts and screws as already described above with reference to FIG. 5 (b) Can be fixedly connected.

At this time, the first bus bar connecting portion 110 'is connected to the center cathode electrode 10'.

Similarly, in FIG. 5 (c), a second pipe composed of the first upper electrode 10b and the first lower electrode 20b, and a second pipe composed of the first upper electrode 10d and the first lower electrode 20d The sides of each of the fourth pipes are located adjacent to the second bus bar connecting portion 120 'and can be fixedly connected to the second bus bar connecting portion 120' through bolts and screws.

Since the first bus bar connecting portion 110 'and the second bus bar connecting portion 120' are configured to transmit currents having different polarities, the electrode portions connected to the electrode portions located inside the pipe 1 The shape of the first bus bar connecting portion 110 'and the shape of the second bus bar connecting portion 120' are different from each other.

(-) current is received by the first bus bar connecting portion 110 'and the negative (-) electrodes connected to the first bus bar connecting portion 110' are connected to the (+) current from the second bus bar connecting portion 120 ' The electrodes disposed on the outer side of the first bus bar 110 protrude in the direction of the first bus bar 110 more than the electrodes received by the second bus bar 110. More specifically, 1 bus bar connection 110 '.

Accordingly, since the first bus bar connecting portion 110 'positioned to contact the negative electrode having such a structure has a multi-stage structure and the protruding positions of the (-) electrode and the (+) electrode are different from each other, One bus bar connecting portion 110 'and the second bus bar connecting portion 120' have different shapes.

That is, the first bus bar connecting portion 110 'and the second bus bar connecting portion 120' may be designed to have different shapes according to the number of the electrode portions formed in the pipe 1, Thereby forming an end.

For example, when the electrolytic apparatus is formed as shown in FIG. 5B, the first and second bus bar connecting portions 110 'and 120' are formed to have a cylindrical shape, and as another example, 5 (c), the first and second busbar connecting portions 110 'and 120' may have a structure in which a plurality of cylindrical-shaped ends are formed .

When the first or second busbar connecting portion 110 'or 120' is formed with a plurality of cylindrical ends, one cylindrical shape and another adjacent cylindrical shape are formed to have different diameters, and a continuous cylindrical shape Has a diameter gradually becoming narrower, and has a multi-stage structure.

However, in one example, when the electrode portion located inside the pipe 1 of the electrolysis apparatus is formed in the polygonal structure described above with reference to FIG. 2, the first bus bar connecting portion 110 'and the second bus bar The connection portion 120 'is formed in a structure in which a plurality of stages are formed in a polyhedron shape and a polyhedron shape.

In this case, when the first and second bus bar connecting portions 110 'and 120' are formed in a polyhedral shape, the portions contacting the electrode portions formed in a polygonal shape are in plane contact with each other, 110 ', 120 ' and the electrode can be easily joined.

As already described above, the first and second busbar joints 110 'and 120' and the electrode portion can be fixedly connected to each other by bolt or screw connection, but in another example, they can be fixedly connected by welding.

Referring to FIG. 6, the connection structure of the bus bar and the electrode in the electrolytic apparatus according to an embodiment of the present invention will be described in more detail.

6, the first bus bar connecting portion 110 'connected to the disc-shaped first bus bar 110 is connected to the first end 110'a and the second end 110'a connected to the first end 110'a, And a step 110'b.

At this time, the first end 110'a of the first bus bar connecting portion 110 'has the screw through grooves 110'g and 110'h, and the second end of the first bus bar connecting portion 110' (110'b) has screw through grooves (110'e, 110'f).

The screw through grooves 110'g and 110'h formed in the first end 110'a are formed to have a shape finer toward the inner direction of the first end 110'a from the surface of the first end 110'a And is a groove for fixing the third pipes 10c and 20c to the first end 110'a.

The fixing parts 110'g and 110'h which are bolts or screws, that is, male screws, pass through the third pipes 10c and 20c and are inserted into the screw through grooves 110'g and 110'h of the first end 110'a 'h to fix the third pipes 10c and 20c in contact with the surface of the first end 110'a to the first end 110'a.

Likewise, the threaded through grooves 110'e and 110'f formed in the second end 110'b are punched toward the inner direction of the second end 110'b from the surface of the second end 110'b And is a groove for fixing the first pipes 10a and 20a to the second end 110'b.

The fixing portions 110'e and 110'f extend through the first pipes 10a and 20a and extend to the inside of the screw through grooves 110'e and 110'f of the second end 110'b, The first pipes 10a and 20a located in contact with the surface of the second stage 110'b are fixed to the second stage 110'b.

The first bus bar connecting portion 110 'is formed in a structure that penetrates the inside of the first bus bar connecting portion 110' along the direction from the first bus bar 110 to the center cathode electrode 10 ' And further includes a groove 110'c, and the center cathode electrode 10 'has a groove 10'a at one end.

At this time, the groove 10'a formed in the center cathode electrode 10 'is a groove formed along the longitudinal direction of the center cathode electrode 10', and is formed only at one end adjacent to the first bus bar connecting portion 110 ' .

The fixing part 10 "a, which is a male screw, penetrates through the screw through groove 110'c of the first bus bar connecting part 110 'is formed in the groove 10'a of the center cathode electrode 10' And the first electrode connection part 110 'and the center cathode electrode 10' are fixedly connected to each other.

The second end 110'b of the first bus bar connecting part 110 'further includes a screw through groove 110'd and the male fixing part 110'd is connected to the first bus bar 110' And the first bus bar 110 and the first bus bar connecting part 110 'are positioned so as to reach the inside of the screw through groove 110'd of the first bus bar connecting part 110' (110 "d).

The electrodes connected to the first or second bus bar connection portions 110 'and 120' in such a structure and receiving current from the first or second bus bar connection portions 110 'and 120' The first upper electrode 10a and the first lower electrode 20a which are cathode electrodes generate a negative current according to the current received from the first bus bar connecting portion 110 ' The reduction reaction according to the electrolysis of the ballast water takes place as shown in the following formula (1).

[Chemical Formula 1]

2H ₂ O + 2e ^- ? H ₂ + 2OH ^-

The first upper electrode 10b and the first lower electrode 20b which are anode electrodes generate a positive current according to the current received from the second bus bar connecting portion 120 ' 2 < / RTI >

(2)

2Cl ^- ? Cl ₂ + 2e ^-

H ₂ O? 0.5O ₂ + 2H ⁺ + 2e-

At this time, Cl2 formed by performing the reaction of the formula (2) on the anode electrode is dissolved in the ballast water flowing in the electrolysis apparatus and performs the following hydrolysis reaction.

Cl ₂ + H ₂ O ^- & gt ^; HOCl + H ⁺ + Cl ^-

HOCl ↔ H ⁺ + OCl ^-

Hyosalic acid (HOCl) ions are generated from the hydrolysis reaction, and hypochlorous acid, which is a disinfectant, can be produced by electrolyzing the ballast water in the electrolyzer.

As described above, the pipe 1 having the electrode portion 100 having the plurality of electrodes 10a and 10b and the spacers 2a and 2b supporting the electrode portion 100, The electrolytic apparatus of the present invention including the first and second bus bars 110 and 120 having the penetrating portions 115 and 125 may be formed in a plurality of connected structures as shown in FIG.

7 and 8, a structure of an electrolysis module connecting a plurality of electrolytic apparatuses according to the present invention will be described. A first rectifier connection unit 210 connected to the rectifier 200 is connected to a second bus bar (120), and transmits the current received from the rectifier (200) to the electrode unit (100) of the electrolytic apparatus.

One of the electrolytic apparatuses connected to the first rectifier connection unit 210 is connected to the other electrolytic apparatus. At this time, the first electrode connection protruding hole 112 Is connected to the second electrode connection protrusion hole 122 formed in the second bus bar 120 of the other electrolysis device so that the two electrolysis devices are connected to each other.

At this time, as the electrode connection part 150, which is a conductor, passes through the first electrode connection protrusion hole 112 and the second electrode connection protrusion hole 122, the first bus bar 110 and the other one of the electrolytic device The first bus bar 120 and the second bus bar 110 are electrically connected to each other by the penetration parts 115 and 125 respectively formed in the first and second bus bars 120 and 120, The ballast water flowing in the pipe 1 of the electrolytic apparatus 1 can be moved into the pipe 1 of the other electrolytic apparatus.

When the plurality of electrolytic devices are continuously connected to each other, a connecting part 300 for connecting the two electrolytic devices is inserted according to the installation position of the electrolytic module to adjust the installation direction of the electrolytic device to constitute the electrolytic module .

This electrolysis module connects the second busbar 120 of the last electrolytic device to the second rectifier connection 220.

The electrolytic apparatus and the electrolytic module including the electrolytic apparatus of the present invention may include a plurality of electrode units 100 and a plurality of electrode units 100 included in one electrolytic unit, The first electrode 10 of the first electrode 10 is also formed in a semi-cylindrical shape, so that it is possible to provide more electrodes than when the conventional plate electrode is installed or the bipolar electrode is included.

As a result, the electrolysis efficiency of the ballast water flowing into the electrolytic apparatus is improved, so that it is possible to generate a high concentration of the sterilizing agent, and the high flow rate can be maintained by designing the interval between the electrodes. It is possible to reduce the generation of the negative electrode scale formed on the cathode of the one electrode 10.

Next, an operation of the electrolytic apparatus according to an embodiment of the present invention to generate sterilizing agent from ship equilibrium water will be described with reference to Figs. 1 to 8. Fig.

First, the ballast water is introduced into the main pipe of the ship ballast water treatment apparatus formed on the ship, and a portion of the ballast water is collected from a pipe branched from the main pipe (hereinafter referred to as a branch pipe).

At this time, a part of the ballast water flowing into the branch piping passes through the electrolysis module installed in the branch piping, and the electrolysis module having a plurality of electrolysis apparatuses and receiving current from the rectifier 200, The ballast water passing through the inside is electrolyzed to produce a bactericide.

The current outputted from the rectifier 200 is transferred to the second bus bar 120 of the electrolysis device through the first rectifier connection part 210 of the electrolysis module and the second bus bar 120 is transferred to the second bus bar 120 A current is supplied to the first electrodes 10a and 20a which are positive electrodes connected to the first electrodes 10a and 120 so that the sterilizing agent is generated by electrolysis of the ballast water at the first electrodes 10a and 20a.

The first bus bar 110 receiving the current output from the rectifier 200 transmits a current to the first electrodes 10b and 20b which are negative electrodes connected to the first bus bar 110, A reduction reaction of the ballast water is performed at the electrodes 10b and 20b.

In the structure of the electrolysis module in which a plurality of different electrolytic devices are connected to each other, the ballast water flows in one direction inside the electrolytic device connected to each other by the hydraulic pressure and the flow velocity of the ballast water flowing from the outside, The ballast water flows through the plurality of electrolytic apparatuses and is electrolyzed by the penetration portions 115 and 125 respectively formed in the first and second busbars 110 and 120 of the electrolytic apparatus.

Therefore, in the plurality of electrolytic apparatuses included in the electrolytic module, the ballast water is electrolyzed by the electrode portion having a plurality of electrodes, and the effect of generating a high concentration of bactericide is obtained.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, It belongs to the scope of right.

1: pipe 10: first electrode
100: electrode unit 110: first bus bar
120: second bus bar 150: electrode connection part
200: rectifier 300: connection

Claims (5)

A semi-cylindrical upper electrode;
A lower electrode having the same size and the same shape as the upper electrode and being in contact with the upper electrode;
A cylindrical pipe having a diameter larger than a length corresponding to the diameter of the upper electrode and positioned to surround the outside of the upper electrode and the lower electrode;
A spacer inserted in the pipe in a direction crossing the pipe and having a groove formed to have a size corresponding to the thickness of the upper electrode and the lower electrode to sandwich the upper electrode and the lower electrode in the groove;
First and second bus bars formed at both ends of the pipe to transmit a current received from the outside to the upper electrode and the lower electrode;
First and second flanges connecting the first and second bus bars and the pipe; And
And a bus bar protrusion formed with first and second electrode connection protrusions for electrically connecting the first and second bus bars to adjacent bus bars,
And a current and a positive current to the first and second bus bars, respectively. The method of claim 1,
At least one further upper electrode having a size to be inserted into the pipe and different in size from the upper electrode,
Further comprising at least one further lower electrode formed in the same size and shape as the at least one further upper electrode and in contact with the further upper electrode,
Wherein the spacer further comprises a groove for fixing the at least one further upper electrode and the at least one further lower electrode. The method of claim 1,
Wherein a periphery of the upper electrode and a periphery of the lower electrode are fitted in the groove of the spacer not at a point where the upper electrode and the lower electrode meet,
Wherein the spacers are formed in at least two intersections in different directions. delete delete

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