KR100458383B1 - Identification system of anode pole for marine structure - Google Patents

Abstract

Disclosed herein are an anode pole identification system and an anode pole for the same, the anode pole identification system includes an anode unit, a power supply unit (300), a transmission module (200) and a reception module (400). The anode unit comprises an anode pole (120) in contact with seawater, and a fastening unit (150) to which the anode unit is detachably combined in an insulated manner and which is fastened to the marine structure. The power supply unit (300) supplies the anode pole with power through at least one power supply line (500). The transmission module (200) is provided near the anode unit to generate Identification (ID) signals. The reception module (400) is provided near the power supply unit (300) to receive and analyze the ID signals from the transmission module (200) and to control a power supply from the power supply unit (300).

Description

IDENTIFICATION SYSTEM OF ANODE POLE FOR MARINE STRUCTURE}

The present invention relates to an electrode system in an offshore structure to prevent marine natives from engrafting on the offshore structure or to prevent corrosion of the offshore structure, and more particularly, to transmit to the electrode part in which the electrode is provided to maintain the quality of the electrode. The present invention relates to an electrode identification system of an offshore structure, in which a module is provided and the transmitting module generates a signal relating to ID information, which the receiving module receives and controls the power supply of the power supply unit.

A large amount of seawater is introduced as cooling water for cooling devices such as desalination plants, seawater magnesia manufacturing plants, and power plants.However, due to the inflow of seawater, spores such as mussels, barnacles, and sea horses attach to and grow in the pipeline. There is a problem. In addition, surfaces such as pipelines react with seawater to generate corrosion.

This problem not only occurs in land-based plants, but also occurs in ships and the like. In other words, the vessel is required to supply seawater for cooling the engine and balancing the vessel (Ballast), the same problem occurs in the area where the seawater is supplied.

In order to solve this problem, the prior art uses the anti-fouling electrode and the anti-corrosion electrode together to prevent the contamination of the structure by marine natives while preventing the contamination of the structure by corrosion.

As a conventional technology related to the present invention, Korean Patent Application Publication No. 2001-0097221 "A marine life habitat prevention apparatus and method thereof", Korean Utility Model Registration No. 249437 "Preventing attachment of marine organisms Apparatus ", International Publication No. WO 89/03261," Method for reducing marine biological pollution ", and the like.

According to the prior art, copper (Cu) is mainly used as an antifouling electrode, and aluminum (Al), iron (Fe), etc. are used as an electrode for corrosion prevention.

In addition, the anticorrosive electrode is known to have a certain antifouling effect as well as the anticorrosive effect, and is generally used together with the antifouling electrode.

1 and 2 are schematic diagrams of a conventional antifouling and anticorrosion system.

1 is a seawater is introduced into the tank, and equipped with a pair of anti-fouling rods for releasing copper ions and a positive electrode rod for releasing aluminum or iron ions, the anode rod for antifouling and anti-corrosion rods receiving AC power A constant current automatic rectifier for supplying DC power is connected to the anti-fouling anode rod and the anti-corrosion anode rod.

FIG. 2 relates to an antifouling and anticorrosion system for seawater flowing into a cooling water into a vessel, and is basically a technology having the same identity as that of FIG. 1.

According to these conventional techniques, an antifouling anode rod and an anticorrosion anode rod are used while contacting with seawater, and an antifouling anode rod and an anticorrosion anode rod are coupled to a fixed part and fixedly coupled to an offshore structure such as a hull and a tank.

On the other hand, anode rods, fixtures, and power supplies (eg, constant current automatic rectifiers) are directly related to the quality of antifouling and anticorrosive systems, so they are all manufactured directly by one manufacturer. As a result of the release, they should be replaced approximately every two years.

When the anode rod is replaced as described above, the new anode rod to be replaced is often manufactured and supplied by a different manufacturer than the original supplier of the antifouling and anticorrosive system.

However, if third-party anode rods are used in antifouling and anticorrosion systems, manufacturers of the original antifouling and anticorrosion systems will find it difficult to maintain the same quality of their products, and this impairment of the quality of the products will affect the credit in the market. There is a risk of massive damage.

Therefore, the present invention provides a transmission module in the electrode portion consisting of the electrode and the fixing device to generate a signal related to the ID information in the transmission module, and receives it from the receiving module provided on the power supply side to supply power to the power supply unit. The present invention seeks to provide an electrode identification system of an offshore structure that can be controlled.

1 and 2 is a schematic diagram of a conventional antifouling and anticorrosion system,

3 is an overall system configuration of one embodiment according to the present invention;

4 is a circuit diagram of the transmission module of FIG. 3;

5 is a circuit diagram of the receiving module of FIG.

6A is a view showing line voltages of a power supply line during normal power supply of the embodiment of FIG. 3;

6B is a view showing line voltages of a power supply line during data transmission in the embodiment of FIG. 3;

7 is a data processing flowchart of a transmitting module and a receiving module of the embodiment of FIG. 3;

8 is a schematic cross-sectional view of an electrode unit according to an embodiment of the present invention.

<Description of Symbols for Main Parts of Drawings>

100: electrode 120: electrode

150: fixing device

200: transmission module

300: power supply

400: receiving module

500: power supply line

In order to solve the above problems, the present invention, the electrode portion which is in contact with sea water and the electrode rod is detachably coupled in an insulating state and comprises a fixing device fixed to the marine structure, the power supply through the power supply line to the electrode rod A power supply unit for supplying, a transmission module provided on the electrode side to periodically generate a signal relating to ID information, and a power supply unit provided on the power supply side to receive and analyze a signal relating to the ID information from the transmission module to supply power to the power supply unit. It characterized in that it comprises a receiving module for controlling the supply.

The above and below ID information is encrypted data stored in the transmission module to indicate the electrode manufacturer and the like. Accordingly, the receiving module analyzes the ID information and controls the power supply unit to stop supplying power when the ID information is not detected or when different ID information is detected.

In the above, the transmitting module generates a signal regarding the life information of the electrode unit, the receiving module is configured to receive and analyze the signal of the life information from the transmitting module to control the power supply of the power supply unit. desirable. The life information in the above and hereinafter refers to the sum of the times that the power is supplied starting from the time when the power supply unit starts supplying power to the electrode unit, particularly the electrode. Accordingly, the receiving module analyzes the life information and controls the power supply unit to stop supplying power when it is determined that the life information exceeds a predetermined period.

In the above, the transmitting module generates a signal relating to the reference date information, the receiving module is preferably configured to control the power supply of the power supply by receiving and analyzing the signal related to the reference date information from the transmitting module. Do. The reference date below and below refers to a specific date such as the date the electrode is manufactured or the date the electrode is shipped from the factory. Accordingly, the receiving module analyzes the reference date and controls the power supply unit to stop supplying power when it is determined that the current date has elapsed for a predetermined period from the reference date.

In the above, it is preferable that the transmitting module induces a pulse on the power supply line by generating the signal, and the receiving module is configured to receive the signal by detecting a pulse of the power supply line. Signal transmission between the transmitting module and the receiving module is always performed through the power supply line, so that only one power supply line is required between the power supply unit and the transmitting module, thereby reducing the cost of installing an antifouling and anticorrosive system. Even when the present invention is introduced into an antifouling and anticorrosion system, it is possible to use a power supply line that is already provided and there is no need to install a separate wire, thereby facilitating its installation.

In the above, the signal may be made of data that is separated through the variation of the pulse width of the pulse voltage.

Hereinafter will be described in detail the configuration and operation according to an embodiment of the present invention.

3 is an overall system configuration of one embodiment according to the present invention.

The power supply unit 300 is connected to the first connection terminal 1 of the transmission module 200 through the power supply line 500. In addition, the power supply unit 300 is connected to the terminal 2 of the receiving module 400 through the power supply line (500). Therefore, the transmission module 200 and the reception module 400 are connected through the power supply line 500.

The power supply unit 300 supplies power, specifically, a constant current through the transmission module 200, and the anode rod 120 is connected to the connection terminal 2 of the transmission module 200 through the stud bolt 110 to supply power. Power is supplied from the supply unit 300. A configuration relationship between the anode rod 120 and the stud bolt 110 is described in detail in FIG. 8.

On the other hand, the power supply unit 300 is connected to the connection terminal 1 of the receiving module 400 to supply a power, specifically, 12V constant voltage for the operation of the receiving module 400.

The transmission module 200 is provided on the electrode part 100 including a positive electrode rod 120 and a fixing device 150 which is detachably coupled in an insulated state and fixed to an offshore structure, and periodically Therefore, a signal relating to ID information, a signal relating to life information, and a signal relating to reference date information are generated to induce a pulse voltage to the power supply line 500. An attachment position of the transmission module 200 will be described in detail with reference to FIG. 8.

Receiving module 400 is provided on the power supply unit 300 side detects the pulse voltage induced in the power supply line 500, the signal related to the ID information generated by the transmission module 200, the signal and reference for life information Receive a signal regarding date information. The receiving module 400 is preferably provided inside the power supply 300.

The receiving module 400 analyzes a signal related to the received ID information, a signal related to the lifetime information, and a signal related to the reference date information, and determines that the positive electrode is not genuine. The signal for cutting off the power supply provided through the power supply line 500 is transmitted.

4 is a circuit diagram of the transmission module of FIG. 3.

The power supply line 500 is connected to the first connection terminal J4, and the power supplied to the first connection terminal J4 is connected to the transmission module via a constant voltage providing circuit consisting of D4, C3, U4, C4, D5, and C5. Provide 5V drive voltage.

In addition, the power supplied to the first connection terminal J4 is connected to the second connection terminal J4 through the switching elements Q1 and IRF 9540, and the second connection terminal J4 is connected to the stud bolt 110 of FIG. It is connected to provide a constant current to the anode rod (120).

Pin 21 of IC chips U5 and PIC16F873 periodically outputs a signal related to ID information, a signal related to lifetime information, and a signal related to reference date information. When the signal is output, transistor Q3 is turned on and transistor Q2 is output. ) Is turned off so that the switching element Q1 is turned off to cut off the power provided to the connection terminal J4, and the first connection terminal J4 connected to the power supply line 500 rises to 12V.

When no signal is output from pin 21 of the IC chips U5 and PIC16F873, the transistor Q3 is turned off, the transistor Q2 is turned on, and the switching element Q1 is turned on to supply power to the connection terminal J4. Is provided, and the first connection terminal J4 connected to the power supply line 500 is maintained at 5V.

5 is a circuit diagram of the receiving module of FIG. 3.

The 12V power supplied to the first connection terminal J1 provides a driving voltage of 5V to the receiving module through a constant voltage providing circuit consisting of C1, U1, and C2.

The power supply line 500 connected through the connecting terminal J1, 2, is connected to the non-inverting terminal of the operational amplifier U3A via R2, and the operational amplifier U3A is connected to the non-inverting terminal 3 and the inverting terminal 2. Compare the input voltage and output + 5V or 0V to pin 21 of IC chip (U2, PIC16F873). That is, 0V is output when the power supply line 500 is 5V, and + 5V is output when the power supply line 500 is 12V.

IC chip (U2, PIC16F873) receives data through pin 21, analyzes the signal on ID information, the signal on lifespan information, and the reference date information to control the power supply of power supply unit 300 with pin 11 Outputs

IC chip U6 constitutes a frequency divider circuit for generating the current date.

FIG. 6A is a diagram showing line voltages of a power supply line during normal power supply of the embodiment of FIG. 3, and FIG. 6B is a diagram showing line voltages of a power supply line during data transmission of the embodiment of FIG.

6A shows the line voltage of the power supply line when power is normally supplied to the anode rod and maintains 5V.

FIG. 6B shows the line voltage of the power supply line when the transmitting module transmits data to the receiving module. The portion forming the pulse of 12V is data, and the data type is determined by the pulse width. For example, as a data type, a total of 19 can be used from 0 to 18, where 0 to 15 means hexadecimal data, 16 indicates the start of transmission of reference date information, 17 indicates the start of transmission of life information, and 18 indicates It can be determined that the transmission of ID information.

7 is a data processing flowchart of a transmitting module and a receiving module according to the embodiment of FIG. 3.

The transmitting module initially stores ID information and reference date information, and the lifetime information is set to zero.

When power is supplied to the transmitting module, the transmitting module transmits ID information stored in the transmitting module to the receiving module (S101).

The ID information is encrypted data stored in the transmission module to indicate the electrode manufacturer and the like.

In S102, the transmitting module transmits life information to the receiving module.

The life information refers to the sum of the times that the power is supplied starting from the time when the power supply starts supplying power to the electrode. Therefore, in S104, the life information is increased by one.

In S103, the transmitting module transmits reference date information to the receiving module.

The reference date refers to the date on which the electrode is manufactured.

In S104, the life information increases by one. Therefore, in the present embodiment, the number of life information corresponds to the number of times that the transmitting module transmits the life information to the receiving module.

In S105, life information is stored in the EEPROM of the transmitting module. This is to prepare for when power is not supplied to the transmission module. When the power supply is resumed, the transmission module reads the life information stored in the EEPROM and continues counting.

In S106, the transmission module is in the standby state for a predetermined time and then repeats the procedure from S101.

On the other hand, the receiving module determines whether the ID information transmitted in S201 matches the ID information stored in the receiving module, and if they do not match, sends a signal to block the power supply of the power supply unit.

It determines the magnitude of the life information transmitted in S202 and the effective lifespan stored in the receiving module, and if the transmitted life information is greater than the effective life, it sends a signal to cut off the power supply of the power supply. The useful life of the electrode is about two years.

In step S203, when it is determined that 1500 days have passed by comparing the current date with the transmitted reference date, a signal for shutting off the power supply of the power supply unit is sent.

8 is a schematic cross-sectional view of an electrode unit according to an exemplary embodiment of the present invention.

The electrode unit 100 is largely composed of the anode rod 120 and the fixing device 150.

The fixing device 150 includes a mounting flange 151 and a mounting sleeve 152.

Lifting lugs 151a are provided on the mounting flange 151, and the mounting flange 151 is provided with a plurality of bolt holes 151b to be bolted to the offshore structure B.

The mounting flange 151 and the mounting sleeve 152 are integrally formed by welding.

The stud bolt 110 is provided in the mounting sleeve 152, and the anode rod 120 is screwed to the lower portion of the stud bolt 110.

Insulation washer 153 is provided on the top for insulation of the stud bolt 110 and the mounting sleeve 152, the double nut 111 is fastened to the top of the insulation washer 153, and the stud bolt 110 The outer circumferential portion of is coated with insulation.

In addition, an insulation washer 154 is inserted therebetween to insulate the anode rod 120 and the mounting sleeve 152.

Therefore, the mounting sleeve 152, the mounting flange 151, and the hull (B) is connected to form a grounded state, and electrically double nut 111, stud bolt 110, anode rod 120 is It is connected.

The transmission module 200 is provided around the double nut 111 inside the mounting sleeve 152. After providing the transmission module 200, the transmission module 200 is surrounded by the FRP resin or the like around the double nut 111. Fill it to be buried.

Therefore, when attempting to release the double nut 111 in order to use a positive electrode rod of another company, the transmission module 200 embedded in the FRP resin and the like is damaged together, so that the receiving module 400 can no longer receive a signal regarding ID information. It can not cut off the power supply of the power supply unit 200.

The above embodiment is only a preferred embodiment of the present invention, the technical idea of the present invention can be variously modified or adjusted by those skilled in the art, and if such a modification or adjustment uses the technical spirit of the present invention, the scope of the present invention It belongs to.

According to the present invention, there is provided a transmission module in the electrode unit to generate a signal related to the ID information in the transmission module, and receiving the signal related to the ID information from the receiving module provided on the power supply side to supply power to the power supply In order to control the antifouling and anticorrosive system operation according to the authenticity of the electrode, it is possible to maintain the same quality of the antifouling and anticorrosion system.

Claims (5)

Electrode part made of an electrode rod in contact with sea water and the electrode rod is detachably coupled in an insulating state and a fixing device fixed to the marine structure, A power supply unit supplying power to the electrode through a power supply line; A transmission module provided on the electrode side and periodically generating a signal relating to ID information; and A receiving module provided at the power supply unit to receive and analyze a signal related to the ID information from the transmitting module to control power supply of the power supply unit; Electrode identification system of the marine structure, characterized in that comprises a. The power supply module of claim 1, wherein the transmission module generates a signal regarding life information of the electrode unit, and the receiving module receives and analyzes a signal about life information from the transmission module to control power supply of the power supply unit. Electrode identification system of the offshore structure, characterized in that made. The power supply module of claim 2, wherein the transmission module generates a signal related to reference date information, and the reception module receives and analyzes a signal related to the reference date information from the transmission module to control power supply of the power supply unit. Electrode identification system of the offshore structure, characterized in that. The transmission module according to any one of claims 1 to 3, wherein the transmission module induces a pulse on the power supply line by the generation of the signal, and the receiving module detects the pulse of the power supply line to receive the signal. Electrode identification system of the offshore structure, characterized in that made. 5. The electrode identification system of claim 4, wherein the signal is composed of data divided by variation of a pulse width of the pulse voltage.