KR102347124B1 - Marine organism antifouling device for seawater battery - Google Patents

Abstract

Disclosed is an apparatus for preventing attachment of marine organisms for seawater batteries. The apparatus for preventing attachment of marine organisms for a seawater battery of the present invention is a device for preventing attachment of marine organisms used in a seawater battery device, wherein the seawater battery device includes a plurality of seawater batteries spaced apart from each other, and a casing for accommodating the seawater batteries and seawater therein. Including, an ultrasonic vibrator coupled to the casing; and a controller for controlling the ultrasonic vibrator, wherein the ultrasonic waves generated by the ultrasonic vibrator are transmitted between the seawater batteries using seawater as a medium. According to the present invention, it is possible to provide an apparatus for preventing attachment of marine organisms for a seawater battery, which is configured to prevent attachment of marine organisms to the surface of the seawater battery even when the flow of fluid is always constant.

Description

Marine life attachment prevention device for seawater battery {MARINE ORGANISM ANTIFOULING DEVICE FOR SEAWATER BATTERY}

The present invention relates to a device for preventing attachment of marine organisms for a seawater battery, and more particularly, to a device for preventing attachment of marine organisms for a seawater battery to prevent marine life from adhering to the seawater battery.

A seawater battery belongs to a chemical battery that converts chemical energy into electrical energy, and uses sodium ions in seawater to enable charging and discharging. A seawater battery is formed in the form of a plate having a predetermined thickness, consisting of an anode, an electrolyte, a separator, a current collector, and the like.

Since such a seawater battery uses sodium ion from seawater as a raw material, there is no limit to the amount of raw material, it can be used free of charge, a battery (battery) can be made at a lower price than a lithium-ion battery, and a low price Therefore, mass production becomes easier, electricity can be supplied even when submerged, and when charging, sodium ions in seawater move into the battery and seawater is desalinated. It has many advantages such as

However, as the seawater battery is submerged in seawater and maintains a state of direct contact with seawater, the marine-origin organic matter floating in the seawater and the larvae of marine attachment organisms, that is, the larvae (or spores) of mussels, barnacles, and sea horses, appear on the surface of the seawater battery. There is a problem in that it is attached to the seawater to interfere with the movement of seawater or to physically damage it.

In particular, there is a problem in that the storage and production efficiency of electrical energy is lowered when marine organisms are attached to the surface of the seawater battery.

As described above, there are various prior art for preventing the attachment of marine organisms to objects in contact with seawater. In this regard, Korean Patent Publication No. 2106376 (hereinafter 'prior literature') discloses a device for preventing attachment of marine organisms for seawater batteries. The apparatus for preventing attachment of marine organisms for seawater batteries of the prior literature is configured to include a reciprocating member and a guide member.

The reciprocating member is connected to each of the interfering stages that are positioned so as to be reciprocally movable between the seawater cells that are arranged at a distance by the fixed frame, and is connected to each end of the interfering stages to be integrated with the interfering stages, and It consists of a connection with a fluid-resisting surface to receive resistance.

The guide member is installed on the housing or the fixed frame, and is coupled to the reciprocating member to guide the reciprocating movement of the reciprocating member. As the pressure according to the flow of the fluid acts on the fluid resistance surface, the reciprocating member is guided by the guide member to move, and the interfering ends physically remove the marine organisms attached to the surface of the seawater battery.

The apparatus for preventing attachment of marine life for seawater batteries of the prior literature, in a state in which long rod-shaped interfering ends are arranged between each seawater battery arranged to maintain a distance from each other, in a state where the connection part is connected to the flow of fluid (flow or wave of seawater, etc.) There is an advantage in that the interfering ends can scrape off the marine organisms attached to the surface of the seawater cells while reciprocating between the seawater cells.

In order for the reciprocating member to reciprocate smoothly, the reciprocating member and the guide member must form a very small frictional force. The guide member is inserted into the holes formed in the four corners of the reciprocating member. Therefore, when the reciprocating member is inclined even a little, the frictional force between the reciprocating member and the guide member increases rapidly.

However, since the flow of the fluid is irregular, it is practically difficult to prevent the inclination of the reciprocating member. Therefore, the apparatus for preventing attachment of marine organisms for seawater batteries of the prior literature has a problem in that it is difficult to move the reciprocating member due to the frictional force formed by the reciprocating member and the guide member during the reciprocating movement of the reciprocating member. In addition, when the flow of the fluid is always constant, the reciprocating movement of the reciprocating member is impossible. Therefore, even if the flow of the fluid is always constant, there is a need for a method capable of removing the marine organisms attached to the surface of the seawater battery.

(Prior Document) Republic of Korea Patent Publication No. 2106376 (Registration date: 2020.04.24)

It is an object of the present invention to provide an apparatus for preventing attachment of marine organisms for a seawater battery, which is configured to smoothly remove marine organisms adhering to the surface of a seawater battery even when the flow of a fluid is constant.

According to the present invention, there is provided an apparatus for preventing attachment of marine organisms used in a seawater battery device, wherein the seawater battery device includes a plurality of seawater batteries spaced apart from each other, and a casing for accommodating the seawater batteries and seawater therein. and an ultrasonic vibrator coupled to the casing; and a controller for controlling the ultrasonic vibrator, wherein the ultrasonic waves generated by the ultrasonic vibrator are transmitted between the seawater cells using the seawater as a medium.

The casing may include a body defining one or more openings; and one or more diaphragms coupled to the body to block the openings, respectively, and to which the ultrasonic vibrator is coupled.

The ultrasonic vibrator is provided on opposite sides of the seawater cells, respectively, and includes transmitting members extending from the ultrasonic vibrator to the seawater cells, respectively, and the ultrasonic waves generated by the ultrasonic vibrator use the transmitting member as a medium. It may be made to be transmitted between the seawater batteries.

The transmission member may include a coupling unit coupled to the ultrasonic vibrator; and a plurality of transfer units connected to the coupling unit and interposed between the seawater batteries.

The ultrasonic vibrator may include: an ultrasonic vibrator; and a housing accommodating the ultrasonic vibrator therein, and being in close contact with the coupling part.

and a shock absorber for applying an electric shock to the seawater, wherein the shock absorber includes a pair of conductors connected to both electrodes of a battery, and the electric current of the battery flows along between the seawater cells through the seawater, The pair of conductors may be provided on opposite sides of the seawater batteries.

The conductor may be in close contact with the coupling portion, and the current of the battery may be transmitted between the seawater batteries through the transmission member.

The conductor may be formed to be surrounded by the housing between the casing and the coupling part.

An elastic body may be interposed between the conductor and the casing, and the elastic body may be configured to form an elastic recovery force so that the conductor is in close contact with the coupling part.

According to the present invention, the ultrasonic waves generated by the ultrasonic vibrator are transmitted between the seawater cells using seawater as a medium, so that even if the flow of fluid is always constant, it is made to prevent the adsorption of organic matter on the surface of the seawater battery, which is a pre-stage of marine life. It becomes possible to provide a biological adhesion prevention device.

In addition, the ultrasonic waves generated by the ultrasonic vibrator are transmitted between the seawater cells using the transmission member as a medium, so that marine organisms attempting to attach to the surface of the seawater battery relatively far from the ultrasonic vibrator cannot access the medium. It is possible to provide a preventive device.

In addition, the current of the battery is transmitted between the seawater cells through the transmission member, thereby preventing the adhesion of organic matter and/or marine adhering organisms to the surface of the seawater battery regardless of the distance away from the ultrasonic vibrator, thereby preventing the organic matter on the surface of the seawater battery. And/or it is possible to provide a device for preventing attachment of marine organisms for a seawater battery so that the action of attachment of marine organisms does not proceed.

1 is a view showing an installation state of an apparatus for preventing attachment of marine organisms for a seawater battery according to an embodiment of the present invention.
FIG. 2 is a view showing a state of use of the apparatus for preventing attachment of marine organisms for a seawater battery of FIG. 1 .
3 and 4 are views illustrating an installation process of the apparatus for preventing attachment of marine organisms of FIG. 2 .
5 is a view showing an apparatus for preventing attachment of marine organisms for a seawater battery according to another embodiment of the present invention.
FIG. 6 is a view showing a state of use of the apparatus for preventing attachment of marine organisms for a seawater battery of FIG. 5 .
7 is a view showing a state of use of the apparatus for preventing attachment of marine organisms for a seawater battery according to another embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, in describing the present invention, descriptions of already known functions or configurations will be omitted in order to clarify the gist of the present invention.

The apparatus for preventing attachment of marine organisms for a seawater battery of the present invention is configured to prevent adhesion of marine organisms to the surface of the seawater battery even if the flow of fluid is always constant.

1 is a view showing an installation state of a marine organism adhesion prevention device 10 for a seawater battery according to an embodiment of the present invention. FIG. 2 is a view showing a state of use of the apparatus 10 for preventing attachment of marine organisms for seawater batteries of FIG. 1 .

As shown in FIG. 1 , the apparatus 10 for preventing attachment of marine organisms for a seawater battery according to an embodiment of the present invention is used (installed) in the seawater battery apparatus 1A.

The seawater battery device 1A may constitute the seawater power generation system 1 together with the seawater purification device 1B. The seawater power generation system 1 may include a seawater battery device 1A, a seawater purification device 1B, and a case 1C.

The seawater battery device 1A and the seawater purification device 1B are accommodated inside the case 1C. One or more doors CD are installed on the upper portion of the case 1C.

The door (CD) is normally closed. The manager of the seawater power generation system 1 may open the door CD and enter the case 1C to manage the seawater battery device 1A and the seawater purification device 1B.

The sea water purification device 1B purifies seawater. The seawater is introduced into the sea water purification device 1B by the water pump BP. An inlet (B1), an outlet (B2) and a drain pipe (B3) are formed in the sea purification apparatus (1B). An on/off valve V is installed at the inlet (B1), the outlet (B2) and the drain pipe (B3), respectively.

As shown in FIG. 1 , seawater is introduced into the sea water purification apparatus 1B through an inlet B1 and then discharged through an outlet B2. The seawater discharged through the outlet (B2) flows into the seawater battery device (1A) through the connecting pipe (B5).

Although not shown, the sea purification apparatus 1B may filter marine organisms and foreign substances contained in seawater by deposition.

For example, the sea purification apparatus 1B may form a plurality of movement paths therein. The movement paths may be formed to be long in the longitudinal direction, respectively. The movement paths may be sequentially connected to each other in the upper and lower portions. The seawater introduced into the sea water purification device 1B may be deposited while repeating ascent and descent along a plurality of movement paths.

The seawater battery device 1A generates electric power through electrolysis of seawater. As shown in Figure 2, the seawater battery device (1A) is configured to include a plurality of seawater batteries (A1), a fixed frame (A2) and a casing (A3).

The plurality of seawater batteries A1 may form a plate shape. The seawater batteries A1 are coupled to the fixed frame A2 in a state in which they are arranged parallel to each other. The seawater batteries A1 are spaced apart from each other. Referring to Korean Patent No. 2106376, the seawater batteries A1 may be vertically spaced apart from each other while coupled to the fixed frame A2.

The casing (A3) accommodates the seawater batteries (A1) and seawater therein. An inlet A33 and an outlet A34 are formed in the casing A3. An on/off valve V is installed at the inlet A33 and the outlet A34, respectively. The seawater discharged from the sea purification device 1B flows into the casing A3 through the inlet A33 and then is discharged to the outside of the casing A3 through the outlet A34.

As shown in Figure 2, the casing (A3) is configured to include a body (A31) and a blocking plate (A32).

The body A31 may have a hexahedral shape. The body A31 defines one or more openings A311 . For example, the body A31 may form an opening A311 on each side thereof. That is, the body A31 may form four openings A311 .

The blocking plate A32 is coupled to the body A31 to block the openings A311, respectively. That is, the blocking plate A32 may be provided in the same number as the opening A311 . FIG. 2 shows a pair of blocking plates A32 blocking two of the four openings A311.

3 and 4 are views showing an installation process of the apparatus 10 for preventing attachment of marine organisms of FIG. 2 .

3 and 4 , the edge portion of the barrier plate A32 is in close contact with the edge of the opening A311 from the outside of the body A31. A sealing member R such as an O-ring may be provided along the edge of the opening A311 . As shown in Figure 1, the blocking plate (A32) may be coupled to the body (A31) by a bolt or the like.

As shown in FIGS. 1 and 2 , the apparatus 10 for preventing attachment of marine organisms for a seawater battery according to an embodiment of the present invention is made so that marine organisms do not adhere to the seawater battery A1, and the ultrasonic vibrator 100 ) and the control unit 300 may be included.

The control unit 300 may be provided on the upper portion of the casing (A3). The controller 300 controls the ultrasonic vibrator 110 . The controller 300 may periodically supply power from the battery BT to the ultrasonic vibrator 110 . Power of the battery BT may be supplied to the ultrasonic vibrator 110 through the wire W.

3 and 4, the ultrasonic vibrator 100 may be coupled to the casing (A3). The ultrasonic vibrator 100 is configured to include an ultrasonic vibrator 110 and a housing 120 .

The housing 120 accommodates the ultrasonic vibrator 110 therein. The housing 120 protects the ultrasonic vibrator 110 from seawater. The housing 120 is coupled to the diaphragm A32.

An ultrasonic oscillator 110 (ultrasonic oscillator) is an oscillator for the purpose of generating ultrasonic waves. The ultrasonic vibrator 110 generates ultrasonic waves in the casing A3.

Ultrasonic waves generated by the ultrasonic vibrator 100 are transmitted between the seawater cells A1 using seawater as a medium. When the ultrasonic vibrator 110 generates ultrasonic waves in seawater, decompression and pressure increase repeatedly appear. In the ultrasonic wave, negative pressure is formed in the decompression half cycle, and fine bubbles are generated due to the cavitation phenomenon.

The generated bubble is contracted (compressed) at the increased pressure, and expanded again at the reduced pressure. As the bubble repeats contraction and expansion, the particle size increases. When the bubble exceeds a certain pressure, it contracts and explodes, generating a large shock wave. The marine organisms attached to the seawater batteries A1 are peeled off and removed by the shock wave.

The ultrasonic vibrator 100 may be provided on opposite sides of the seawater batteries A1, respectively. Therefore, the ultrasonic wave generated by the ultrasonic vibrator 100 is transmitted between the seawater cells A1 from both sides of the seawater cells A1.

5 is a view showing an apparatus 20 for preventing attachment of marine organisms for a seawater battery according to another embodiment of the present invention. FIG. 6 is a view showing a state of use of the apparatus 20 for preventing attachment of marine organisms for seawater batteries of FIG. 5 .

As shown in FIGS. 5 and 6 , the apparatus 20 for preventing attachment of marine life for seawater batteries according to another embodiment of the present invention includes an ultrasonic vibrator 100 , a transmission member 200 and a control unit 300 . can be

The control unit 300 may be provided on the upper portion of the casing (A3). The controller 300 controls the ultrasonic vibrator 110 . The controller 300 may periodically supply power from the battery BT to the ultrasonic vibrator 110 . Power of the battery BT may be supplied to the ultrasonic vibrator 110 through the wire W.

5 and 6, the ultrasonic vibrator 100 may be coupled to the casing A3. The ultrasonic vibrator 100 is configured to include an ultrasonic vibrator 110 and a housing 120 .

The housing 120 accommodates the ultrasonic vibrator 110 therein. The housing 120 protects the ultrasonic vibrator 110 from seawater. The housing 120 is coupled to the diaphragm A32.

An ultrasonic oscillator 110 (ultrasonic oscillator) is an oscillator for the purpose of generating ultrasonic waves. The ultrasonic vibrator 110 generates ultrasonic waves in the casing A3.

When the ultrasonic vibrator 110 generates ultrasonic waves in seawater, decompression and pressure increase repeatedly appear. In the ultrasonic wave, negative pressure is formed in the decompression half cycle, and fine bubbles are generated due to the cavitation phenomenon.

The generated bubble is contracted (compressed) at the increased pressure, and expanded again at the reduced pressure. As the bubble repeats contraction and expansion, the particle size increases. When the bubble exceeds a certain pressure, it contracts and explodes, generating a large shock wave. Microorganisms that cause the attachment of marine organisms to the seawater batteries A1 are peeled off and removed by the shock wave. Accordingly, it is possible to prevent and/or reduce the adhesion of marine organisms to the seawater batteries A1.

As shown in FIG. 6 , the transmission member 200 extends from the ultrasonic vibrator 100 to the seawater cells A1 , respectively. The transmission member 200 is configured to include a coupling unit 210 and a plurality of transmission units 220 .

The coupling unit 210 is coupled to the ultrasonic vibrator 100 . In more detail, the coupling part 210 may be bolted to the housing 120 . The coupling part 210 is in close contact with the housing 120 by the fastening force of the bolt. Therefore, the ultrasonic wave generated by the ultrasonic vibrator 100 is directly transmitted to the coupling unit 210 .

The transfer unit 220 is formed to extend between the seawater batteries A1 from the coupling unit 210, respectively. The transfer units 220 are interposed between the seawater batteries A1. Accordingly, the ultrasonic wave generated by the ultrasonic vibrator 100 is transmitted to the transmission unit 220 through the coupling unit 210 .

As a result, the ultrasonic wave generated by the ultrasonic vibrator 100 is transmitted between the seawater cells A1 using the transmitting member 200 as a medium, and is transmitted from the transmitting member 200 to the seawater between the seawater cells A1. Therefore, the cavitation phenomenon caused by the ultrasonic waves generated by the ultrasonic vibrator 100 may actively occur between the seawater cells A1.

The ultrasonic vibrator 100 and the transmission member 200 may be provided on opposite sides of the seawater batteries A1, respectively. Therefore, the ultrasonic wave generated by the ultrasonic vibrator 100 is transmitted between the seawater cells A1 through the transmission member 200 as a medium on both sides of the seawater cells A1.

7 is a view showing a state of use of the apparatus 30 for preventing attachment of marine organisms for a seawater battery according to another embodiment of the present invention.

As shown in FIG. 7 , the apparatus 30 for preventing attachment of marine organisms for seawater batteries according to another embodiment of the present invention includes an ultrasonic vibrator 100 , a transmission member 200 , a control unit 300 and an electric shock device 400 . It may be composed of

The control unit 300 may be provided on the upper portion of the casing A3 (see FIG. 5 ). The controller 300 controls the ultrasonic vibrator 110 and the electric shock device 400 . The control unit 300 may periodically and selectively supply power from the battery BT to the ultrasonic vibrator 110 and the electric shock device 400 . Power of the battery BT may be supplied to the ultrasonic vibrator 110 and the shock absorber 400 through the wires W.

7, the ultrasonic vibrator 100 may be coupled to the casing (A3). The ultrasonic vibrator 100 is configured to include an ultrasonic vibrator 110 and a housing 120 .

The housing 120 accommodates the ultrasonic vibrator 110 therein. The housing 120 protects the ultrasonic vibrator 110 from seawater. The housing 120 is coupled to the diaphragm A32.

An ultrasonic oscillator 110 (ultrasonic oscillator) is an oscillator for the purpose of generating ultrasonic waves. The ultrasonic vibrator 110 generates ultrasonic waves in the casing A3.

When the ultrasonic vibrator 110 generates ultrasonic waves in seawater, decompression and pressure increase repeatedly appear. In the ultrasonic wave, negative pressure is formed in the decompression half cycle, and fine bubbles are generated due to the cavitation phenomenon.

The generated bubble is contracted (compressed) at the increased pressure, and expanded again at the reduced pressure. As the bubble repeats contraction and expansion, the particle size increases. When the bubble exceeds a certain pressure, it contracts and explodes, generating a large shock wave. Organic matter causing attachment of marine organisms to the seawater batteries A1 is peeled off and removed. Accordingly, it is possible to prevent and/or reduce the adhesion of marine organisms to the seawater batteries A1.

As shown in FIG. 7 , the transmission member 200 extends from the ultrasonic vibrator 100 to the seawater cells A1 , respectively. The transmission member 200 is configured to include a coupling unit 210 and a plurality of transmission units 220 .

The coupling unit 210 is coupled to the ultrasonic vibrator 100 . In more detail, the coupling part 210 may be bolted to the housing 120 . The coupling part 210 is in close contact with the housing 120 by the fastening force of the bolt. Therefore, the ultrasonic wave generated by the ultrasonic vibrator 100 is directly transmitted to the coupling unit 210 .

The transfer unit 220 is formed to extend between the seawater batteries A1 from the coupling unit 210, respectively. The transfer units 220 are interposed between the seawater batteries A1. Accordingly, the ultrasonic wave generated by the ultrasonic vibrator 100 is transmitted to the transmission unit 220 through the coupling unit 210 .

As a result, the ultrasonic wave generated by the ultrasonic vibrator 100 is transmitted between the seawater cells A1 using the transmitting member 200 as a medium, and is transmitted from the transmitting member 200 to the seawater between the seawater cells A1. Therefore, the cavitation phenomenon caused by the ultrasonic waves generated by the ultrasonic vibrator 100 may actively occur between the seawater cells A1.

The ultrasonic vibrator 100 and the transmission member 200 may be provided on opposite sides of the seawater batteries A1, respectively. Therefore, the ultrasonic wave generated by the ultrasonic vibrator 100 is transmitted between the seawater cells A1 through the transmission member 200 as a medium on both sides of the seawater cells A1.

As shown in FIG. 7 , the electric shock device 400 is configured to apply electric shock to seawater, and includes a pair of conductors 410 connected to both electrodes of the battery BT.

Any one of the pair of conductors 410 is connected to the positive electrode of the battery BT by a wire W. The other of the pair of conductors 410 is connected to the negative electrode of the battery BT by a wire W.

A pair of conductors 410 are provided opposite to each other with respect to the seawater cells A1 so that the current of the battery BT flows along between the seawater cells A1 through seawater.

The ultrasonic vibrator 100 and the transmission member 200 are provided on opposite sides of the seawater batteries A1, respectively.

Holes into which the conductors 410 are inserted are formed in the housings 120 provided opposite to each other based on the seawater batteries A1. The hole is opened (A311) toward the coupling portion (210). The conductor 410 is surrounded by the housing 120 between the casing A3 and the coupling portion 210 . Accordingly, the conductor 410 is protected from seawater by the housing 120 and the coupling portion 210 .

An elastic body 420 is interposed between the conductor 410 and the diaphragm A32. The elastic body 420 may be provided with a rubber spring, a coil spring, or the like.

The elastic body 420 is provided in a contracted (compressed) state between the conductor 410 and the diaphragm A32. The elastic body 420 forms an elastic recovery force between the conductor 410 and the barrier plate (A32). Accordingly, the conductor 410 is in close contact with the coupling portion 210 by the elastic recovery force of the elastic body 420 .

The transmission member 200 is made of a material that transmits electricity well, such as iron, copper, and aluminum. Therefore, when the power of the battery BT is supplied to the shock absorber 400 , the current of the battery BT is transmitted between the seawater batteries A1 through the transmission members 200 in close contact with both conductors 410 .

While the current of the battery BT passes through the seawater between the seawater cells A1, an electric shock is applied to the marine organisms attached to the surface of the seawater battery A1. Therefore, an electric shock phenomenon due to the current passing through the seawater may actively occur between the seawater batteries A1.

According to the present invention, the ultrasonic waves generated by the ultrasonic vibrator are transmitted between the seawater cells using seawater as a medium, so that even if the flow of the fluid is always constant, the adhesion of organic substances, which provides the cause of adhesion of the attached organisms to the surface of the seawater battery, is removed in advance. Accordingly, it is possible to provide a device for preventing the attachment of marine organisms to the surface of the seawater battery.

In addition, the ultrasonic waves generated by the ultrasonic vibrator are transmitted between the seawater cells using the transmission member as a medium, thereby preventing the adsorption of organic matter on the surface of the seawater battery relatively far from the ultrasonic vibrator and preventing the attachment of marine organisms. It is possible to provide a preventive device.

In addition, the current of the battery is transmitted between the seawater cells through the transmission member, thereby preventing the adhesion of marine organisms for seawater batteries by preventing the adsorption of organic matter on the surface of the seawater battery regardless of the distance away from the ultrasonic vibrator device can be provided.

In the foregoing, specific embodiments of the present invention have been described and illustrated, but it is common knowledge in the art that the present invention is not limited to the described embodiments, and that various modifications and variations can be made without departing from the spirit and scope of the present invention. It is self-evident to those who have Accordingly, such modifications or variations should not be individually understood from the technical spirit or point of view of the present invention, and the modified embodiments should belong to the claims of the present invention.

10: device for preventing attachment of marine organisms
100: ultrasonic vibrator 300: control unit
110: ultrasonic vibrator BT: battery
120: housing 400: electric shock device
W: wire 410: conductor
200: transmission member 420: elastic body
210: coupling part
220: transmission unit
1: Seawater power generation system
1A: Seawater battery system 1B: Seawater purification system
A1 : Seawater battery BP : Pump
A2 : Fixed frame B1 : Inlet
A3: Casing B2: Outlet
A31 : Body B3 : Drain pipe
A311 : Opening B5 : Connector
A32: baffle plate 1C: case
A33: Entrance CD: Door
A34: Exit
V : on/off valve
R: sealing member

Claims (9)

A device for preventing attachment of marine organisms used in a seawater battery device, comprising:
The seawater battery device includes a plurality of seawater batteries spaced apart from each other, and a casing for accommodating the seawater batteries therein,
an ultrasonic vibrator coupled to the casing; and
A control unit for controlling the ultrasonic vibrator,
The ultrasonic vibrator transmits ultrasonic waves between the seawater batteries,
Including an electric shock device for applying an electric shock to the seawater accommodated in the casing,
The stunner includes a pair of conductors connected to both electrodes of the battery,
The apparatus for preventing attachment of marine organisms for seawater batteries, characterized in that the pair of conductors are provided on opposite sides with respect to the seawater cells so that the electric current of the battery flows along between the seawater cells through the seawater. According to claim 1,
The casing is
a body defining one or more openings; and
and one or more blocking plates coupled to the body to block the openings, respectively, and to which the ultrasonic vibrator is coupled. According to claim 1,
The ultrasonic vibrator is provided on opposite sides of the seawater batteries, respectively,
and a transmission member each extending between the seawater batteries from the ultrasonic vibrator,
The ultrasonic wave generated by the ultrasonic vibrator is transmitted between the seawater cells using the transmission member as a medium. 4. The method of claim 3,
The transmission member,
a coupling unit coupled to the ultrasonic vibrator; and
Connected to the coupling part, the marine life attachment prevention device for a seawater battery, characterized in that it comprises a plurality of transfer parts interposed between the seawater batteries. 5. The method of claim 4,
The ultrasonic vibrator,
ultrasonic vibrator; and
and a housing for accommodating the ultrasonic vibrator therein and in close contact with the coupling part. delete 6. The method of claim 5,
The conductor is in close contact with the coupling portion,
The current of the battery is transferred between the seawater cells through the transmission member, marine life attachment prevention device for a seawater battery, characterized in that. 8. The method of claim 7,
The conductor is a marine life attachment prevention device for a seawater battery, characterized in that it is surrounded by the housing between the casing and the coupling part. 9. The method of claim 8,
An elastic body is interposed between the conductor and the casing,
The apparatus for preventing attachment of marine organisms for seawater batteries, characterized in that the elastic body forms an elastic recovery force so that the conductor is in close contact with the coupling part.

Images