KR101011631B1 - An apparatus and a method for a non-input power electric corrosion prevention - Google Patents

Abstract

PURPOSE: An NECP(Non-Input Power Electric Corrosion Prevention) apparatus and method are provided to generate anticorrosion current without commercial AC power using harmful AC voltage which is naturally generated. CONSTITUTION: An NECP apparatus comprises a potential measuring unit(2) and an anticorrosion current generator(1). The potential measuring unit measures harmful AC voltage(AC) which is induced between electrolyte(G.L) and a metal structure(M) by the ambient environment and flows into the metal structure. The anticorrosion current generator generates anticorrosion current(DC) using at least a part of the harmful AC voltage as power source according to the measured size of the harmful AC voltage. The potential measuring unit comprises a regulator which distributes the harmful AC voltage to at least a part of the harmful AC voltage used as power source and unused residual harmful AC voltage, and a switch and an earth electrode(5) which discharge the residual harmful AC voltage if the residual harmful AC voltage exceeds a reference value.

Description

Non-powered electrical method and method {AN APPARATUS AND A METHOD FOR A NON-INPUT POWER ELECTRIC CORROSION PREVENTION}

The present invention by using at least a portion of the alternating voltage, that is, the harmful alternating voltage naturally induced by the natural environment to the metal structure embedded in the electrolyte as the power energy, the electrical system of the metal structure without using a separate AC commercial power source ( Non-input power Electric Corrosion Prevention Apparatus (NECP) to prevent electrical corrosion by generating anti-corrosion current for the electrical current and to discharge the harmful alternating voltage remaining after use. It is about a method.

In general, as can be seen in the conventional electrical system R of Figure 3 (a), the metal structure (M) (e.g., piping) installed in the electrolyte GL (e.g., underground, underwater or concrete, etc.) , When the AC voltage flows into the oil pipeline, gas pipe, tank, foundation pile or rebar, etc., the metal structure (M) buried in the ground is electrically corroded, shortening the lifespan and risk of electric shock. Should not be removed or the incoming alternating current voltage should be discharged to the surroundings (ground) for removal. The inflow of alternating current into the metal structure (M) is due to the induced voltage formed by overhead wires or underground wires installed for supplying electricity from KEPCO, and the current flowing in the ground, that is, the ground current. Therefore, in order to prolong the life of the structure and to prevent electrical safety accidents, the AC voltage flowing into the metal structure M must be extinguished or reduced within at least 15V range.

Here, the term “corrosion” means that “the metal structure (M) is electrochemically reacted by the factors of the metal itself and alternating voltage induced naturally in the ground, so that ions in the metal, ie, electrons, are damaged on the metal structure (M). It refers to the oxidation of the metal itself by leaving through the site. Where metal ions are released, corrosion proceeds rapidly, and eventually the metal structure M is damaged and stops its function.

For example, if gas pipes, oil pipelines, water pipes, etc. are corroded and formed, holes must be restored to their original state by replacing the corrosion sites. To this end, the supply of raw materials must be stopped, resulting in economic loss and social safety problems.

In order to prevent such corrosion, conventionally, the coating is primarily coated on the metal structure (M), but coating damage is caused during operation, and the coating alone cannot completely prevent corrosion. Therefore, as an electrical method for the complete method of the metal structure, the so-called Cathodic Protection Method is applied together.

In general, the metal structure M installed in the ground GL has a different potential difference depending on the type (material) of the metal. In the case of steel, the copper sulfate (Cu / CuSO ₄ ) reference electrode has a potential difference in the ground from about -450 mV to about -650 mV. This potential difference is called the natural potential, and this natural potential is the corrosion potential. If this natural potential is lowered below the standard value of the anticorrosive potential -850mV (the number becomes larger), the corrosion of steel will stop. Therefore, the anticorrosive current is forcibly supplied by the cathodic protection method to lower the natural potential and maintain the anticorrosive potential below -850 mV.

According to the conventional cathodic protection method, the conventional electric device on the right side of FIG. 3 (a) contacts the reference electrode 3 to the surface of the ground GL adjacent to the metal structure M (e.g., a gas pipe). Connect the lead wire of the reference electrode 3 to the negative terminal of the potentiometer, and connect the measurement line for potential measurement from the gas pipe (M) to the positive terminal of the measuring unit 2 to read the value of the instrument. At this time, the value read out (the value displayed on the instrument) is a potential applied to the gas pipe (M), and according to the magnitude of the potential, the rectifier can adjust the size of AC commercial power supplied to the rectifier (R) according to the magnitude of the appropriate method current. Create (DC). As the anticorrosive current is generated, as shown by the arrow, the anticorrosive current flows from the anticorrosive anode 4 to the gas pipe M of the anticorrosive object, which is the negative electrode (-), through the ground GL. . As described above, the conventional electric system uses a commercial AC power source separately to forcibly supply the anticorrosive current, so that the corrosion current is removed to stop the release of ions from the gas tube (M). ) Corrosion is prevented. However, at this time, the harmful AC voltage introduced into the gas pipe M is not erased and remains as it is.

When the anticorrosive current is released, for example, when the reference electrode 3 is a copper sulfate electrode, when the potential value measured in the gas pipe M becomes -850 mV or less (the number becomes larger), the gas pipe M is closed. In other words, it is determined that the state is in a corrosion protection state, and, on the contrary, when the measured potential value is -850 mV or more (the number becomes smaller), it is determined that the state is a corrosion state, that is, a non-corrosive state.

For example, when the metal structure M is long like a gas pipe, and the distance between the end of the gas pipe M and the position where the electric system is installed is far, the potential gradient as shown in the solid line graph of FIG. Therefore, it is necessary to adjust the voltage supplied to the rectifier (R) so that the anticorrosive potential is from the lowest potential -2,500mV to the highest potential -850mV. However, if a sufficient current is not supplied in some sections of the gas pipe (M) terminal or harmful AC flows separately, an anti-corrosion current section occurs as shown in the drawing. In this case, unless a separate electrical system is added, the corrosion of the gas pipe (M) is still not prevented, and there is a problem that safety and electrical safety accidents exist in the maintenance of the gas pipe (M).

It is an object of the present invention to provide a novel non-powered electric type device capable of generating anti-corrosion current for preventing corrosion by using the harmful AC as a power source without using a separate AC commercial power source to solve the problem as described above. Its purpose is to.

Another object of the present invention is to provide a novel non-powered electrical method that can generate the anticorrosive current to prevent corrosion by using the harmful AC as a power source without using a separate AC commercial power source.

According to one aspect of the present invention, the AC voltage measuring unit for measuring the harmful alternating current (AC) introduced between the electrolyte (GL) and the gas pipe (M) under the influence of the surrounding environment flowing into the metal structure (M), According to the magnitude of the measured harmful AC voltage is provided a non-powered electrical apparatus including a corrosion current generator for generating a corrosion current (DC) of a corresponding magnitude by using at least a portion of the harmful current as a power source energy.

According to another feature of the present invention, it is induced naturally between the electrolyte (GL) and the gas pipe (M) under the influence of the ambient environment to measure the harmful current flowing into the metal structure (M) and also generate the anticorrosive current (DC) AC voltage measuring instrument for measuring residual residual alternating current voltage and remaining method, anticorrosive potential measuring instrument for measuring anticorrosive potential applied to gas pipe (M) after generating the anticorrosive current, and the measured residual harmful alternating voltage may exceed the reference voltage. When the switch for discharging the residual harmful current, Provided is a non-powered electrical apparatus including at least one switch and rectifying means selected to generate a corresponding anticorrosive current according to the measurement result of the potentiometer and generating an anticorrosive current using the harmful alternating voltage as power energy. do.

According to another feature of the present invention, the harmful alternating current (AC) is naturally induced between the electrolyte (GL) and the gas pipe (M) under the influence of the surrounding environment to enter the gas pipe (M), and the measured According to the magnitude of the noxious alternating voltage, at least a part of the nominal alternating voltage having a corresponding magnitude is used as power energy to generate an anticorrosive current, and an anticorrosive potential applied to the gas pipe (M) after generating the anticorrosive current and the power energy. An electric power-free electric method for measuring the residual harmful currents in succession and then discharging the residual harmful currents when the measured residual harmful currents exceed the reference voltage, thereby maintaining the safety and safety of the gas pipe (M). A method is provided.

According to another aspect of the invention, the potential measuring unit for adjusting the harmful alternating voltage to at least a portion of the harmful alternating voltage used as the power energy and the remaining harmful alternating current voltage, and the remaining harmful alternating current Provided is a non-powered electrical apparatus further comprising a switch and a ground electrode for discharging when the voltage exceeds a reference value.

According to another feature of the present invention, the electric potential measuring unit for measuring the harmful AC voltage adjusted by the adjusting means and the generation of the anticorrosive current of the anticorrosive current generator, the gas pipe (M) Provided is a non-powered electrical apparatus further comprising an anticorrosive potentiometer for measuring the remaining anticorrosive potential.

 According to another aspect of the present invention, there is provided a non-powered electrical device comprising a switch for switching the contact point A and B at a neutral contact to selectively connect the AC voltage meter and the anticorrosive potential meter. .

According to another feature of the invention, the anticorrosive current generator generates at least one switch selected according to the magnitude of the AC voltage detected in the gas pipe (M), and the anticorrosive current of different magnitudes operated by the selected switch A non-power supply comprising: at least one rectifying means, a connection terminal unit for emitting the anticorrosive current generated by the rectifying means through an anticorrosive anode, and an anticorrosive current measuring instrument for measuring the generated anticorrosive current. An electrical device is provided.

According to another feature of the invention, the step of measuring the harmful alternating current (AC) induced between the electrolyte (GL) and the gas pipe (M) by the influence of the surrounding environment flowing into the gas pipe (M), and the measured harmful According to the magnitude of the AC voltage, using the at least a portion of the harmful AC voltage as a power source energy to generate a corrosion resistance current (DC) of a suitable magnitude, and the remaining harmful AC voltage which is the remaining portion of the harmful AC voltage is not used A non-powered electrical method is provided that includes discharging when a value is exceeded.

According to another feature of the present invention, there is provided a non-powered electric method further comprising the step of measuring the residual method current flowing in the gas pipe (M) after the method current is generated.

According to another feature of the invention, further comprising the step of adjusting the magnitude of the power energy larger when the method potential is less than the reference value, and selecting to generate a method current of a magnitude corresponding to the adjustment Anticorrosive methods are provided.

The non-powered electrical apparatus (NECP) of the present invention may use only the apparatus of the present invention alone, but as shown in (a) of FIG. 3, it may be used in combination with the conventional electrical apparatus R. Particularly, since hazardous alternating voltage, which has been left unattended in the past, can be used as power energy, power costs and additional equipment costs can be omitted, and the remaining hazardous alternating voltage can be discharged to secure electrical safety. The maintenance is economical, and the safety is excellent, and as shown in the anticorrosive graph of FIG. 3 (b), it occurs at the gas pipe (M) end portion remote from the conventional electric system (R). It can be seen that the anticorrosive potential shortage section and the anticorrosive potential graph by the conventional electric apparatus are improved from the solid line graph to the dotted line graph. This improvement is great because it can be obtained without using a separate external power source.

DETAILED DESCRIPTION Hereinafter, embodiments of the present invention in which the apparatus of the present invention is applied to corrosion prevention of the gas pipe M will be described in detail with reference to the accompanying drawings.

1 is a schematic diagram of a non-powered electrical apparatus (NECP) according to an embodiment of the present invention;
FIG. 2 is a circuit diagram of the non-powered electrical apparatus of FIG. 1; FIG.
Figure 3 (a) is a schematic diagram showing an application example of the combination of the electrical method (NECP) of the present invention to the conventional electrical method (R), (b) is the anticorrosive potential improved by the application example of (a) Graph representing.

In FIG. 1, the electrical method device (NECP) according to the present invention includes a method current generator 1 and an electric potential measuring part 2, which are connected to the reference electrode 3 and the ground electrode 5 installed in the ground GL. The gas pipes M embedded in the ground are respectively installed in parallel. The harmful AC voltage induced in the ground GL and introduced into the gas pipe M as a straight arrow is measured by the potential measuring unit 2, and at least a part of the harmful AC voltage is converted into power energy according to the measured result. By using the anti-corrosive current generator (1) to generate a corresponding anti-corrosive current (DC) selectively and then to the ground (GL) through the anti-corrosion anode (4) as a curved arrow, without using a separate power source In addition to achieving the desired electrical method, if the residual harmful AC voltage remaining after use is higher than the reference potential, by removing the discharge through the ground electrode (5), the harmful AC voltage is destroyed or reduced, thereby ensuring the electrical safety. .

Referring to the detailed circuit diagram of FIG. 2 to describe in more detail the configuration of the non-powered electrical apparatus (NECP) of the present invention of FIG.

The electric potential measuring unit 2 includes an AC voltage measuring instrument 21 for measuring a harmful AC voltage between the gas pipe M and the reference electrode 3 of the ground GL, and a corrosion current after the anticorrosive current is generated and released. It consists of an anti-corrosive potential meter 22 for measuring the anti-corrosive potential to be removed and remaining in the gas pipe (M), and a switch 33 for sequentially measuring the AC voltage meter 21 and the anti-corrosive potential meter 22, In addition, the control means 26 is adjustable so as to appropriately distribute the measured harmful alternating voltage to the anticorrosive current generator 1 and the potential measuring section 2, and the harmful alternating voltage distributed to the potential measuring section 2 is alternating. When measured by the voltage meter 21 further includes a switch 32 for discharging to the ground electrode 5 when the reference voltage exceeds the 15V range.

Here, the adjusting means 26 is preferably constituted by a variable resistor as an adjusting means for distributing harmful alternating voltage. Therefore, by adjusting the adjusting means 26, it is possible to control the magnitude of the nominal alternating voltage applied to the anticorrosive current generator 1 and the nominal alternating voltage applied to the potential measuring unit 2. The switch 32 is preferably composed of an on / off switch, and the switch 33 is preferably composed of a switching switch switched from the neutral to the contact A or B. When the switch 33 is switched to the contact A, the AC voltage meter 21 measures and displays the harmful AC voltage applied between the gas pipe M and the ground GL, and then switches to the contact B, the anticorrosive potential The measuring instrument 22 displays the anticorrosion potential DC between the gas pipe M and the ground GL.

In the anticorrosive current generator 1, at least one switch 27, 28, 29 is provided for selectively connecting at least one rectifying means 23, 24 or 25 provided between the gas pipe M and the ground GL. At least one on / off switch, the anticorrosive current DC generated by the selected rectifier means is detected and displayed on the anticorrosive current measuring device 31 through the connection terminal unit 30 and is discharged to the anticorrosive anode 4. .

Referring to the non-powered electric method according to the present invention, when the resistance value of the adjusting means 26 is adjusted to zero while the switch 32 is turned off and the switch 33 is connected to the contact A, the gas pipe M The entire harmful current flowed into the AC voltage meter 21 can be confirmed. At this time, the resistance value of the adjusting means 26 is adjusted according to the magnitude of the identified total harmful AC voltage, and the portion to be used as the power energy of the total harmful AC voltage is supplied to the anticorrosive current generator 1, and the remaining portion which is not used is the potential. After distribution to supply to the measuring unit 2, selecting one of the switches (27, 28, 29) generates the anticorrosive current (DC) by the selected rectification means (23, 24, 25) to the positive electrode (4) Is discharged into the ground (GL) through the flow into the gas pipe (M). At this time, the generated anticorrosive current (DC) is confirmed in the anticorrosive current measuring unit 31, and in the AC voltage measuring unit 21, harmful harmful portions distributed to the electric potential measuring unit 1, that is, residual residual exchange portions remaining as power energy, It is confirmed. After that, when the contact of the switch 33 is connected to B, the anticorrosive potentiometer 22 eliminates the corrosion current and checks whether the anticorrosive potential remaining is within a predetermined reference value.

At this time, when the anticorrosive potential is less than or equal to the safe anticorrosive reference potential (-2.5V), after adjusting the adjusting means 26, a corresponding suitable rectifying means 23, 24 or 25 is selected to provide a safe anticorrosive reference potential (-2.5V). You should be able to do this. When the anticorrosive potential after adjustment is within the predetermined range, when the divided residual AC voltage portion exceeds 15 V at maximum, the switch 32 is closed to discharge to the ground electrode 5 to dissipate or reduce the residual AC portion.

In addition, it is preferable that all the wires embedded in the ground GL be a cable wire that can prevent electrical leakage.

Although the present invention as described above has been described with reference to the embodiments shown in the drawings, this is merely exemplary, and common knowledge in the art to which the art belongs without departing from the spirit of the present invention and the appended claims. Those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom. For example, it will be appreciated that the measurement and manipulation may be manually operated in the present invention, but may be made to be operated automatically.

(One); Anticorrosive current generators (2); Potentiometer (3); Reference electrode
(4); Anticorrosive anode 5; Ground electrode 21; Hazardous AC Voltage Meter
(22); Anticorrosive potentiometers (23, 24, 25); Rectification means
(26); Adjusting means 27, 28, 29; Switch 30; Connection terminal part
(31); Anticorrosive current meter (32); A switch 33; switch
NECP; Electrical Apparatus of the Invention
R; Conventional Electric Device
M; Metal structure
GL; Electrolyte

Claims (11)

A potential measurement unit (2) which is induced between the electrolyte (GL) and the metal structure (M) by the influence of the surrounding environment and measures the harmful alternating current (AC) flowing into the metal structure (M);
A non-powered electric generator comprising a method of generating a current (DC) of a corresponding magnitude by using at least a part of the harmful current as a power source energy according to the magnitude of the measured harmful current. Anticorrosive device. The method of claim 1, wherein the potential measuring section 2
And an adjusting means (26) for distributing the noxious alternating voltage to at least a portion of the noxious alternating voltage (AC) used as the power energy and the remaining noxious alternating current (AC). Electrical device. The method of claim 1 or 2, wherein the potential measuring section (2)
And a switch (32) and a ground electrode (5) for discharging when the residual harmful alternating current (AC) exceeds a reference value. 4. The potential measurement unit 2 according to claim 3,
And an AC voltage measuring device (21) for measuring the harmful AC voltage adjusted by the adjusting means (26). The potential measurement unit 2 according to claim 4,
After the generation of the anti-corrosive current of the anti-corrosive current generator (1), characterized in that it comprises a anti-corrosive potential measuring device (22) for measuring the anticorrosive potential applied to the metal structure (M). The method of claim 5, wherein the potential measuring section (2)
And a switch (33) for switching between contacts A and B at a neutral contact to selectively measure the AC voltage meter and the anticorrosive potential meter. The method of claim 1 or 5, wherein the anticorrosive current generator (1)
At least one switch (27, 28, 29) selected according to the magnitude of the noxious current exchange voltage detected in the metal structure (M);
And at least one rectifying means (23, 24, 25) for generating anticorrosive currents of different magnitudes operated by said selected switch. The method of claim 7, wherein the anticorrosive current generator (1)
A connection terminal part 30 for discharging the anticorrosive current generated by the rectifying means 23, 24, 25 through the anticorrosive anode 4;
Non-powered electrical method device comprising a method current measuring device for measuring the generated method current. Measuring noxious current alternating current (AC) induced between the electrolyte (GL) and the metal structure (M) by the influence of the surrounding environment and flowing into the metal structure (M);
Generating an anticorrosive current (DC) of a corresponding magnitude using at least a portion of the noxious ac voltage as power energy according to the magnitude of the noxious ac voltage; And
And discharging when the remaining harmful AC voltage, which is the remaining part of the hazardous AC voltage, does not exceed the reference value. 10. The method of claim 9, further comprising measuring the anticorrosive potential of the metal structure (M) after the anticorrosive current is generated. The method of claim 10, wherein the anticorrosive potential is
Adjusting the magnitude of the power energy to be larger when the reference value is less than the reference value;
And selecting to generate an anticorrosive current of a magnitude corresponding to the adjustment.

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