KR20230106803A - Electrolysis Device, Flow Distribution Device and Method for Electrolysis Device - Google Patents

Abstract

Disclosed is a flow distribution device applied to an electrolysis device for sterilizing ship ballast water.
The flow distribution device for the electrolysis device, the central hole located in the center; an inner ring-shaped portion having the same center as the center hole and surrounding the center hole; a plurality of main holes formed outside the inner ring-shaped portion and surrounding the inner ring-shaped portion; A plurality of main wings installed in the plurality of main holes, respectively, forming a predetermined angle with the surface of the flow distribution device; a plurality of flesh parts respectively formed between the plurality of main holes spaced apart; and an edge portion formed outside the plurality of main holes and surrounding the plurality of main holes.

Description

Electrolysis Device, Flow Distribution Device and Method for Electrolysis Device

The present invention relates to an electrolysis device and a flow distribution device and method applied to the electrolysis device, and more particularly, to an electrolysis device for sterilizing ballast water and applied to the electrolysis device to resist seawater. It relates to a device and method for distributing a flow rate in a manner of imparting (rotational force).

Ballast water refers to seawater that is filled into tanks installed at the bottom or left and right of the ship to maintain the center of gravity during ship operation. catch the

Since various ecosystem disturbances and marine pollution occur in the process of dumping ballast water into the sea, treatment is performed to prevent ecosystem disturbance and marine pollution before dumping ballast water into the sea. Ballast water can be sterilized by electrolysis to maintain it at a certain level.

In general, an electrolysis device used to sterilize ballast water electrolyzes ballast water at room temperature using expensive metals such as platinum and palladium as catalysts. Therefore, in the prior art, there has been a problem that the cost of a catalyst is high in order to use an electrolysis device for sterilizing ship ballast water.

In addition, in the conventional electrolysis device for sterilizing ballast water, the seawater is concentrated in the center of the channel and the flow rate is increased. there was

An object of the present invention is to provide an electrolysis device capable of solving the above problems of a conventional electrolysis device for sterilizing ship ballast water, and a flow distribution device and method for the electrolysis device.

According to one aspect of the present invention for achieving the above object, there is provided a flow distribution device applied to an electrolysis device for sterilizing ballast water, comprising: a center hole positioned at a center; an inner ring-shaped portion having the same center as the center hole and surrounding the center hole; a plurality of main holes formed outside the inner ring-shaped portion and surrounding the inner ring-shaped portion; A plurality of main wings installed in the plurality of main holes, respectively, forming a predetermined angle with the surface of the flow distribution device; a plurality of flesh parts respectively formed between the plurality of main holes spaced apart; And a flow distribution device for an electrolysis device including an edge portion formed around the plurality of main holes on the outside of the plurality of main holes is provided.

The flow distribution device for the electrolysis device includes an outer ring-shaped portion having the same center as the central hole and formed outside the plurality of main holes and surrounding the plurality of main holes; a plurality of auxiliary holes formed around the outer ring-shaped portion outside the outer ring-shaped portion; and a plurality of auxiliary wings respectively installed in the plurality of auxiliary holes and forming a predetermined angle with the surface of the flow distribution device, wherein the edge portion extends around the plurality of auxiliary holes to the outside of the plurality of auxiliary holes. It is formed around, and the flesh part may extend to a distance between the auxiliary holes.

Lengths of the plurality of auxiliary holes may be shorter than lengths of the plurality of main holes.

Each of the plurality of main holes may be located on a fan-shaped plane centered on the center of the central hole.

Each of the plurality of auxiliary holes may be located on a plane extending from a fan-shaped plane where each of the plurality of main holes is located.

A plurality of auxiliary holes may be formed on a fan-shaped plane where one main hole is located.

The flesh part may gradually become thicker from the inside to the outside.

A distance between a plurality of auxiliary holes formed on a fan-shaped plane where one main hole is located may be smaller than a thickness of the flesh part.

According to another aspect of the present invention for achieving the above object, an electrode module for electrolyzing seawater; There is provided an electrolysis device comprising a; and a flow distribution device for imparting rotational force to seawater flowing into the electrode module.

The electrode module includes a plurality of separators forming channels through which seawater flows; an accommodating member accommodating the plurality of separators therein; and a cover member forming an upper or lower surface of the accommodating member and connecting the plurality of accommodating members when there are a plurality of accommodating members.

The electrolysis device further includes a housing accommodating the accommodating member therein, and the housing has an inlet through which seawater flows in and an outlet through which seawater is discharged, and the seawater introduced into the housing through the inlet is It may pass through channels formed inside the receiving member and be discharged through the outlet.

An opening may be formed in the housing, the accommodating member may be inserted into the opening, and the cover member may cover an upper or lower portion of the housing to form an exterior together with the housing.

The electrolysis device may include: a first sensor installed at the inlet of the housing to measure the flow rate and pressure of seawater; And a second sensor installed at the outlet of the housing to measure the flow rate and pressure of seawater; One or more of them may be further included.

The electrolysis device receives a flow rate value and a pressure value measured by one or more of the first sensor and the second sensor and malfunctions through database construction using a real time operating system (RTOS). A control unit for performing diagnosis may be further included.

According to another aspect of the present invention for achieving the above object, in the flow distribution method applied to an electrolysis device for sterilizing ship ballast water, a flow distribution device is installed at an inlet of the electrolysis device, and the flow distribution device After forming a plurality of holes, a plurality of wings are installed in each of the plurality of holes, and the angle, number, distance from the center of the plurality of wings, the size of the center hole formed in the flow distribution device, the flow distribution device There is provided a flow distribution method for an electrolysis device in which at least one of the lengths of the plurality of holes formed in is adjusted to adjust the distribution of the flow rate.

Angles of the plurality of blades may all be controlled to the same angle.

Angles of the plurality of wings may be controlled to different angles.

The plurality of wings may include a plurality of main wings having a longer length and positioned closer to the center, and a plurality of auxiliary wings having a shorter length than the main wings and positioned farther from the center than the main wings.

Angles of the plurality of main wings may all be controlled as a first angle, and angles of the plurality of auxiliary wings may all be controlled as a second angle.

In the electrolysis device, the main wing may include 6 to 12, and the auxiliary wing may include 12 to 24.

If the flow rate of seawater is fast, the efficiency of electrolysis may decrease due to insufficient contact time with the electrode module. According to the present invention, the seawater flowing into the electrolysis device is not concentrated in the center and can be evenly distributed throughout the channel, A sufficient contact time between the seawater and the electrode can be secured. Therefore, even if a small amount of catalyst is used, the efficiency of electrolysis can be maintained, and economic feasibility can be secured through the reduction of catalyst use.

In addition, according to the present invention, by equally distributing the flow rate of seawater to each channel, it is possible to increase electrolysis efficiency by minimizing the occurrence of hot spots that cause intensive reactions locally.

In addition, according to the present invention, by simply coupling the flow distribution device to the inlet of the electrolysis device, it is possible to equally distribute the seawater flow rate without substantially changing the structure of the ballast water system.

1 is a perspective view schematically showing an electrolysis device to which a flow distribution device according to a preferred embodiment of the present invention is applied.
2 is a schematic cross-sectional view of an electrolysis device to which a flow distribution device according to a preferred embodiment of the present invention is applied.
3 is a plan view schematically showing a flow distribution device according to a preferred embodiment of the present invention.
4 is a graph showing flow distribution in each channel according to the blade angle of the flow distribution device as an error rate of average flow rate.
5 is a graph showing flow distribution in each channel according to the number of blades of the flow distribution device as an error rate of average flow rate.
6 is a graph showing the distribution of flow rate in each channel according to the distance of the wing from the center of the flow distribution device as an error rate of the average flow rate.
7 is a graph showing flow distribution in each channel of an electrolysis device to which a flow distribution device according to a preferred embodiment of the present invention is applied, as an average flow rate error rate.
8 is a graph showing changes in TRO efficiency of an electrolysis device to which a flow distribution device according to a preferred embodiment of the present invention is applied.

Hereinafter, the configuration and operation of a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings. The following examples may be modified in many different forms, and the scope of the present invention is not limited to the following examples.

1 is a perspective view schematically showing an electrolysis device to which a flow distribution device according to a preferred embodiment of the present invention is applied, and FIG. 2 is a schematic view of an electrolysis device to which a flow distribution device according to a preferred embodiment of the present invention is applied. It is one section.

1 and 2, the electrolysis device to which the flow distribution device of this embodiment is applied includes an electrode module 100, a flow distribution device 200, and a housing 300, and the electrode module 100 is a cover. It includes a member 101, a receiving member 102 and a plurality of separators 103.

The electrode module 100 sterilizes the seawater by electrolyzing the seawater flowing in the channel divided by the separator 103. Direct current (DC) is supplied to the electrode module 100, and electrons are combined with hydrogen ions at the cathode to generate hydrogen, and at the anode, hydroxyl moves from the electrolyte to the anode. Oxygen is produced by taking electrons from ions. Through this process, hydrogen and chlorine oxide ions are generated, and then, within the concentration range of 40 to 65 mg/L of bromide contained in seawater, H++OCL- (chlorine oxide ion) is converted into H++OBr- (bromide oxide) ions) are converted into Chlorine oxide ion and bromide oxide have bactericidal power and perform sterilization of ship ballast water.

The cover member 101 covers the upper or lower portion of the housing 300 to protect internal components together with the housing 300 and forms the exterior of the electrolysis device. 1 and 2, it is shown that the cover member 101 covers the upper part of the housing 300 to form the upper surface of the electrolysis device.

The cover member 101 may form an upper or lower surface of the accommodating member 102, and connects the plural accommodating members 102 when there are a plurality of accommodating members 102. 1 and 2 , it is shown that the cover member 101 connects the four accommodating members 102 and forms the upper surface of each accommodating member 102 .

The accommodating member 102 accommodates a plurality of separators 103 therein. The accommodating member 102 may be formed in plural, and four may be formed as shown in FIGS. 1 and 2 . Since seawater flows from the inlet 301 of the housing 300 to the outlet 302, the accommodating member 102 is formed to open in the flow direction of the seawater.

The separator 103 is inside the accommodating member 102 (inside the space formed by the accommodating member 102 and the cover member 101 when the cover member 101 forms the upper or lower surface of the accommodating member 102) It is accommodated in and forms a channel through which seawater flows. That is, the space divided by the separator 103 becomes a channel.

The housing 300 accommodates the accommodating member 102 therein, protects internal parts and forms the exterior of the electrolysis device. The housing 300 is formed with openings into which the accommodating members 102 can be inserted. When there are a plurality of accommodating members 102, the number of openings corresponding to the number of accommodating members 102 is formed. 1 and 2 show that four receiving members 102 are accommodated through four openings formed in the housing 300, respectively.

An inlet 301 through which seawater is introduced and an outlet 302 through which seawater is discharged are formed in the housing 300 . Seawater flows into the housing 300 through the inlet 301 and then passes through channels formed inside the accommodating member 102 and is discharged through the outlet 302 . 1 shows that the inlet 301 and the outlet 302 are circular, but the size and shape of the inlet 301 and the outlet 302 may be variously modified.

The flow distribution device 200 is installed at the inlet 301 of the housing 300 so that seawater flows into the housing 300 through the inlet 301 after passing through the flow distribution device 200 . Although the flow distribution device 200 is illustrated in FIG. 1 in a circular shape, the size and shape of the flow distribution device 200 may be variously modified. However, it is preferable that the size and shape of the flow distribution device 200 correspond to the size and shape of the inlet 301 .

The flow distribution device 200 of the present invention is configured in such a way that it is installed in the inlet 301 of the housing 300 without being integrally formed with the housing 300, and has an advantage of easy maintenance.

3 is a plan view schematically showing a flow distribution device according to a preferred embodiment of the present invention.

Referring to FIG. 3 , the flow distribution device 200 of this embodiment has a center hole 250 located at the center and an inner ring shape having the same center as the center hole 250 and surrounding the center hole 250 . Upper part 210, a plurality of main holes 260 formed around the inner ring-shaped part 210 outside the inner ring-shaped part 210, and a plurality of main wings respectively installed in the plurality of main holes 260 ( 280), a plurality of flesh parts 240 each formed between the plurality of main holes 260 spaced apart, and an edge formed around the plurality of main holes 260 on the outside of the plurality of main holes 260. It includes section 230. Seawater is introduced through the central hole 250 and the plurality of main holes 260 .

Hereinafter, 'center' refers to the center of the central hole 250, 'outside' refers to a side far from the 'center', and 'inside' refers to a side close to the 'center'.

The flow distribution device 200 of this embodiment has an outer ring-shaped portion 220 having the same center as the central hole 250 and formed around the plurality of main holes 260 outside the plurality of main holes 260 and , A plurality of auxiliary holes 270 formed outside the outer ring-shaped part 220 around the outer ring-shaped part 220 and a plurality of auxiliary wings 290 respectively installed in the plurality of auxiliary holes 270 are further included. can do. When the outer ring-shaped portion 220 and the plurality of auxiliary holes 270 are formed in the flow distribution device 200, the edge portion 230 is formed around the plurality of auxiliary holes 270 on the outside of the plurality of auxiliary holes 270. It is formed around, and seawater is introduced through a central hole 250, a plurality of main holes 260 and a plurality of auxiliary holes 270. In addition, the flesh part 240 extends until the auxiliary hole 270 is spaced apart. That is, each of the plurality of flesh portions 240 extends from the inner ring-shaped portion 210 to the edge portion 230 passing through the space between the main hole 260 and the space between the auxiliary hole 270 .

The plurality of main holes 260 may have the same shape as each other, and the plurality of auxiliary holes 270 may also have the same shape as each other. In addition, the length of the auxiliary hole 270 (the distance from the closest point to the farthest point from the center, hereinafter the same) may be shorter than the length of the main hole 260 .

Each of the plurality of main holes 260 may be located on a fan-shaped plane centered on the center of the central hole 250 . In addition, each of the plurality of auxiliary holes 270 may be located on a plane extending from a fan-shaped plane on which the plurality of main holes 260 are located, and a fan-shaped plane on which one main hole 260 is located. A plurality of auxiliary holes 270 may be formed thereon. 3 shows that two auxiliary holes 270 are formed on a fan-shaped plane where one main hole 260 is located.

The flesh part 240 may have a shape gradually becoming thicker from the inside to the outside, but is not limited thereto. For example, the flesh part 240 may be formed to have the same thickness. In addition, the interval between the plurality of auxiliary holes 270 formed on the fan-shaped plane where the one main hole 260 is located may be smaller than the thickness of the flesh part 240 .

Since the seawater flows into the inlet 301 of the housing 300 after passing through the flow distribution device 200, the main wing 280 and the auxiliary wing 290 follow the flow of seawater to the inside (ie, the inlet 301). side) is preferred.

The main blade 280 and the auxiliary blade 290 are controlled to form a certain angle with the surface of the flow distribution device 200 . Hereinafter, the 'angle' of the wings 280 and 290 means an acute angle among angles formed between the wings 280 and 290 and the surface of the flow distribution device 200 .

All main blades 280 and auxiliary blades 290 may be controlled to form the same angle, but all main blades 280 may be controlled to a first angle and all auxiliary blades 290 may be controlled to a second angle. there is. In addition, the angles of the wings 280 and 290 may be controlled differently from each other.

When the wings 280 and 290 form a certain angle with the surface of the flow distribution device 200, rotational force (resistance) is given to seawater entering the inlet 301. The smaller the angle of the wings 280 and 290 (that is, the more the wings 280 and 290 block the holes 260 and 270), the greater the rotational force (resistance) received by the seawater, and the angle of the wings 280 and 290 The greater the (ie, the smaller the wings 280 and 290 block the holes 260 and 270), the smaller the rotational force (resistance) received by the seawater, so that the user controls the angle of the wings 280 and 290 so that the flow rate is as desired by the user can be distributed.

As well as the angle of the blades 280 and 290, the number of blades 280 and 290, the distance from the center of the blades 280 and 290, the size of the center hole 250, the length of the main hole 260, and the auxiliary hole The distribution of the flow rate can be adjusted by changing design variables such as the length of 270, and the flow rate of seawater flowing into each channel can be equally distributed by appropriately changing the design variables according to the various shapes and capacities of the electrolysis device. can

The flow of seawater according to the angle of the wings 280 and 290, the number of the wings 280 and 290, and the distance from the center of the wings 280 and 290 is as follows.

4 is a graph showing flow distribution in each channel according to the blade angle of the flow distribution device as an error rate of average flow rate. (a) of FIG. 4 shows a case where the angle of the blades 280 and 290 of the flow distribution device 200 is relatively small, and (b) of FIG. 4 shows the blades 280 and 290 of the flow distribution device 200. ) shows the case where the angle of is greater than (a) in FIG. 4, and (c) in FIG. it is shown

Referring to (a) to (c) of FIG. 4 , as the angle of the wings 280 and 290 decreases, it can be seen that the flow rate concentrated in the center decreases and the flow rate concentrates at the edges. When the angle of the blades 280 and 290 decreases, the rotational kinetic energy applied to the seawater increases and the flow rate entering the channel is concentrated to the edge. According to the present invention, by appropriately controlling the angles of the blades 280 and 290, it is possible to balance the flow rate of the central portion and the edge of the channel and evenly distribute the flow rate of seawater.

5 is a graph showing flow distribution in each channel according to the number of blades of the flow distribution device as an error rate of average flow rate. 5 (a) shows a case where the number of blades 280 and 290 of the flow distribution device 200 is relatively small, and FIG. 5 (b) shows the blades 280 and 290 of the flow distribution device 200 5 (a) shows a case in which the number is greater than FIG. 5 (a), and FIG. 5 (c) shows a case in which the number of blades 280 and 290 of the flow distribution device 200 is greater than that in FIG. 5 (b).

Referring to (a) to (c) of FIG. 5 , it can be seen that as the number of wings 280 and 290 increases, the flow rate concentrated in the center decreases and the flow rate concentrates toward the edge. According to the present invention, by appropriately controlling the number of blades 280 and 290, it is possible to balance the flow rate of the central portion and the edge of the channel, and evenly distribute the flow rate of seawater.

The number of main wings 280 of the present invention may be 6 to 12, more preferably 12. In addition, the number of auxiliary wings 290 of the present invention may be 6 to 24, more preferably, two auxiliary wings 290 are installed per main wing 280, so that the number of auxiliary wings 290 may be 12 to 24, more preferably 24. The inventors of the present invention, as shown in FIG. 3 through repeated experiments, found that the flow distribution device 200 includes 12 main wings 280 and 24 auxiliary wings 290, the center and edge of the channel. It was confirmed that the balance of the flow rate of

6 is a graph showing the distribution of flow rate in each channel according to the distance of the wing from the center of the flow distribution device as an error rate of the average flow rate. Figure 6 (a) shows the case where the wings (280, 290) of the flow distribution device 200 are located relatively close to the center, Figure 6 (b) is the wing of the flow distribution device 200 ( 280 and 290) are located further from the center than in (a) of FIG. 6, and (c) of FIG. It indicates the case where it is located far from the center.

Referring to (a) to (c) of FIG. 6 , it can be seen that as the wings 280 and 290 are located farther from the center, the flow rate concentrated in the center decreases and the flow rate concentrates toward the edge. According to the present invention, by appropriately controlling the distance of the blades 280 and 290 from the center, it is possible to balance the flow rate of the central portion and the edge of the channel and distribute the flow rate of seawater equally.

7 is a graph showing flow distribution in each channel of an electrolysis device to which a flow distribution device according to a preferred embodiment of the present invention is applied, as an average flow rate error rate. Referring to FIG. 7 , it can be seen that in the electrolysis device to which the flow distribution device according to a preferred embodiment of the present invention is applied, the flow rate of seawater flowing to the center and the flow rate of seawater flowing to the edge are almost similar.

8 is a graph showing a change in TRO (Total Residual Oxidant) efficiency of an electrolysis device to which a flow distribution device according to a preferred embodiment of the present invention is applied. The black line in FIG. 8 shows the case where the electrode module 100 is a mass production module to which no coating is applied, and the red line shows the case where the electrode module 100 is a mass production module with 70% reduction in palladium and 2.0 μm of TiN. The blue line shows the case where the electrode module 100 is a mass production module, and the case where the palladium is reduced by 80% and the coating is not applied, and the pink line shows the degree of salinity.

Referring to FIG. 8 , in the mass production module, the flow of flow is located in the central portion without a diffusion plate, and electrolysis is performed through a local intensive reaction in a channel in the central portion. In addition, it can be confirmed that the coated model does not decrease in efficiency compared to the mass-produced model even when palladium is reduced by up to 70% to generate the same efficiency as the mass-produced model, and when a diffusion plate is applied, palladium can be reduced by 80% Confirmed. Economic feasibility can be secured through the same efficiency and reduction of palladium, and maintenance is easy as the accumulation of deposits in the channel can be minimized while reducing the use of catalysts. According to the present invention, as the flow distribution device 200 is applied to the electrolysis device, it can be confirmed that the use of a catalyst can be reduced and the TRO efficiency can be maintained.

In the electrolysis device to which the flow distribution device of the present embodiment is applied, a first sensor installed at the inlet 301 of the housing 300 to measure the flow rate and pressure of seawater is installed at the outlet 301 of the housing 300, The second sensor that measures the flow rate and pressure of seawater receives the flow rate value and pressure value measured by the first and second sensors and establishes a database using a real time operating system (RTOS). It may further include one or more of the controllers performing fault diagnosis through the.

It is obvious to those skilled in the art that the present invention is not limited to the above embodiments and can be variously modified or modified without departing from the technical gist of the present invention. it did

100: electrode module 101: cover member
102: receiving member 103: separator
200: flow distribution device 210: inner ring-shaped portion
220: outer ring-shaped portion 230: edge portion
240: flesh part 250: center hole
260: main hole 270: auxiliary hole
280: main wing 290: auxiliary wing
300: housing 301: inlet
302: exit

Claims (20)

In the flow distribution device applied to the electrolysis device for sterilizing ship ballast water,
a center hole located in the center;
an inner ring-shaped portion having the same center as the center hole and surrounding the center hole;
a plurality of main holes formed outside the inner ring-shaped portion and surrounding the inner ring-shaped portion;
A plurality of main wings installed in the plurality of main holes, respectively, forming a predetermined angle with the surface of the flow distribution device;
a plurality of flesh parts respectively formed between the plurality of main holes spaced apart; and
A flow distribution device for an electrolysis device comprising an edge portion formed around the plurality of main holes on the outside of the plurality of main holes. The method of claim 1,
an outer ring-shaped portion having the same center as the central hole and formed outside the plurality of main holes and surrounding the plurality of main holes;
a plurality of auxiliary holes formed around the outer ring-shaped portion outside the outer ring-shaped portion; and
A plurality of auxiliary wings installed in each of the plurality of auxiliary holes and forming a predetermined angle with the surface of the flow distribution device; further comprising,
The edge portion is formed around the plurality of auxiliary holes on the outside of the plurality of auxiliary holes,
The flesh portion extends until the auxiliary hole is spaced apart, the flow distribution device for an electrolysis device. The method of claim 2,
The length of the plurality of auxiliary holes is shorter than the length of the plurality of main holes, the flow distribution device for the electrolysis device. The method of claim 2,
The flow distribution device for an electrolysis device, wherein each of the plurality of main holes is located on a fan-shaped plane centered on the center of the central hole. The method of claim 4,
The plurality of auxiliary holes are respectively located on the extended plane of the fan-shaped plane at which the plurality of main holes are located, respectively, the flow distribution device for the electrolysis device. The method of claim 5,
A flow distribution device for an electrolysis device, wherein a plurality of auxiliary holes are formed on a fan-shaped plane where one main hole is located. The method of claim 1,
The flesh portion gradually becomes thicker from the inside to the outside, the flow distribution device for the electrolysis device. The method of claim 6,
The interval between the plurality of auxiliary holes formed on the fan-shaped plane where one main hole is located is narrower than the thickness of the flesh part, the flow distribution device for the electrolysis device. An electrode module that electrolyzes seawater; and
The flow distribution device according to any one of claims 1 to 8 for imparting rotational force to seawater flowing into the electrode module;
Including, electrolysis device. The method of claim 9,
The electrode module,
A plurality of separators forming channels through which seawater flows;
an accommodating member accommodating the plurality of separators therein; and
a cover member forming an upper or lower surface of the accommodating member and connecting the plurality of accommodating members when there are a plurality of accommodating members;
Including, electrolysis device. The method of claim 10,
Further comprising a housing for accommodating the receiving member therein,
An inlet through which seawater is introduced and an outlet through which seawater is discharged are formed in the housing,
Seawater introduced into the housing through the inlet passes through channels formed inside the accommodating member and is discharged through the outlet. The method of claim 11,
An opening is formed in the housing,
the receiving member is inserted into the opening;
The cover member covers the upper or lower portion of the housing to form an exterior together with the housing. The method of claim 11,
A first sensor installed at the inlet of the housing to measure the flow rate and pressure of seawater; and
A second sensor installed at the outlet of the housing to measure the flow rate and pressure of seawater; Further comprising one or more of, an electrolysis device. The method of claim 13,
A control unit that receives a flow rate value and a pressure value measured by one or more of the first sensor and the second sensor and performs a failure diagnosis through a database establishment using a real time operating system (RTOS) Further comprising, an electrolysis device. A flow distribution method applied to an electrolysis device for sterilizing ship ballast water,
A flow distribution device is installed at the inlet of the electrolysis device,
After forming a plurality of holes in the flow distribution device, a plurality of wings are installed in each of the plurality of holes,
Controlling the distribution of the flow rate by changing at least one of the angle, number, distance from the center of the plurality of wings, the size of the center hole formed in the flow distribution device, and the length of the plurality of holes formed in the flow distribution device, A flow distribution method for an electrolysis unit. The method of claim 15
The angles of the plurality of blades are all controlled at the same angle, a flow distribution method for an electrolysis device. The method of claim 15
The angles of the plurality of blades are each controlled at different angles, a flow distribution method for an electrolysis device. The method of claim 15
The plurality of wings include a plurality of main wings that are longer in length and positioned closer to the center, and a plurality of auxiliary wings that are shorter in length than the main wings and positioned farther from the center than the main wings. Flow distribution method for devices. The method of claim 18
The angles of the plurality of main wings are all controlled to a first angle,
The angles of the plurality of auxiliary blades are all controlled at a second angle, a flow distribution method for an electrolysis device. The method of claim 18
The main wings include 6 to 12,
The auxiliary wing is a flow distribution method for an electrolysis device comprising 12 to 24 pieces.

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