KR20130079836A - Real time monitoring method of corrosion and water quality using by-pass unit in a heating system and real time monitoring system using the same - Google Patents

Abstract

PURPOSE: A method for monitoring water quality and a corrosion property in a thermal fluid feeding pipe using a bypass and a monitoring system using the same are provided to remarkably improve accuracy in the measurement of the corrosion property due to the water quality. CONSTITUTION: A method for monitoring water quality and a corrosion property in a thermal fluid feeding pipe (1) using a bypass includes: a step of partially or wholly extracting heating water inside the pipe, and injecting the water into a chamber; a step of measuring the quality of the water inside the chamber; a step of submerging a specimen in the water inside the chamber, and measuring the corrosion property of the specimen; and a step of re-injecting the water inside the chamber into the pipe.

Description

REAL TIME MONITORING METHOD OF CORROSION AND WATER QUALITY USING BY-PASS UNIT IN A HEATING SYSTEM AND REAL TIME MONITORING SYSTEM USING THE SAME}

The present invention relates to a method for monitoring the water quality and corrosion characteristics of a thermal fluid transport pipe using a bypass and a monitoring system using the same. By providing a method of monitoring the corrosion characteristics, it is possible to accurately identify the corrosion characteristics of the thermal fluid transport pipe in real time, and by using a bypass, it is possible to connect the monitoring system directly without interruption of the operation of the thermal fluid transport pipe. The present invention relates to a method for monitoring the water quality and corrosion characteristics of a thermal fluid transport pipe using economical bypass and a monitoring system using the same.

The heating water pipe satisfies the water quality according to the standard through the water treatment, thereby extending the corrosion life of the pipe. Nevertheless, in addition to uniform corrosion due to inflow of oxygen, local pH change, and scale formation, local corrosion may occur, which may cause serious damage to pipes such as crevices and formulas.

In fact, recently, the occurrence of leakage due to sedimentation corrosion, welding corrosion, immersion by flow velocity has been reported at home and abroad.

Currently, water quality monitoring system is used in various companies, but no system has been developed to identify the factors that directly affect the corrosion of steel pipes by measuring the quality of heating water flowing in the pipe and the corrosion rate inside the pipe in real time. .

In addition, the current monitoring system has a problem that may affect the actual heating water supply system, and the heating water is collected, analyzed in the laboratory, and immersed in the specimen. However, this requires a lot of time for analysis, it is difficult to cope with sudden changes in the water quality, there is a problem that takes a lot of cost.

Therefore, it is necessary to develop a system that can not only quickly and accurately identify the corrosion characteristics of the heating water in relation to the water quality, but also identify the corrosion status in real time without affecting the actual heating water supply system. It is becoming.

The present invention is to solve the above problems, unlike the prior art, by considering the elements optimized for the heat fluid transport pipe which is a moving passage of heating water, by providing a method for monitoring the water quality and corrosion characteristics, the heat fluid transport pipe according to the water quality It is an object of the present invention to provide a method for monitoring the water quality and corrosion characteristics of a thermal fluid transport pipe using a bypass which significantly increases the accuracy of corrosion characteristics measurement, and a monitoring system using the same.

In addition, by using the detour optimized for the heating water supply system, it is possible to connect the monitoring system directly without interruption of the operating heat fluid transport pipe, so that it can be easily applied to the real environment and heat fluid transport using economical bypass It is an object of the present invention to provide a method for monitoring water quality and corrosion characteristics of pipes and a monitoring system using the same.

In addition, by optimizing the factors affecting the corrosion of the thermal fluid transport tube, it is possible to effectively grasp the corrosion characteristics of the thermal fluid transport pipe according to the water quality with a minimum number of sensors, as well as the corrosion of the thermal fluid transport pipe such as a three-electrode sensor. It is an object of the present invention to provide a method for monitoring the water quality and corrosion characteristics of a thermofluid transport pipe using a bypass that can quickly measure corrosion characteristics with minimal equipment, and a monitoring system using the same.

Method for monitoring the water quality and corrosion characteristics of the thermal fluid transport pipe using the bypass according to the present invention for achieving the above object, the extraction step of extracting part or all of the heating water inside the heat fluid transport pipe, and put into the chamber ; A water quality measuring step of measuring the quality of the heating water in the chamber; A corrosion characteristic measurement step of dipping the specimen in the heating water in the chamber to measure the corrosion characteristic of the specimen; And a re-insertion step of introducing the heating water in the chamber back into the thermal fluid transport pipe.

And analyzing in real time a correlation between the water quality and the corrosion characteristics measured in the water quality measurement step and the corrosion property measurement step, wherein the extracting step comprises heating the inside of the thermal fluid transport pipe. Due to the pressure difference between the water pressure and the chamber, the heating water is extracted.

In addition, the extraction step, characterized in that the pressure of the chamber 5 to 25% lower than the pressure of the heating water in the heat fluid transport pipe, in the water quality measurement step, the water quality measurement of the heating water in the chamber, In the chamber, a sensor capable of measuring at least one of dissolved oxygen, pH, electrical conductivity, flow rate, or temperature may be installed in real time.

In the corrosion characteristic measurement step, the corrosion characteristic measurement of the specimen, the calculation of at least one of the polarization resistance or the corrosion rate measured using a three-electrode sensor including a reference electrode, a working electrode and a counter electrode, using an electrical resistance sensor It is characterized in that the corrosion rate is calculated or at least one of the calculation of the corrosion rate by measuring the mass loss of the specimen.

In addition, the re-supply step, characterized in that the heating water in the chamber is introduced into the thermal fluid transport pipe due to the pressure difference between the pressure of the heating water in the chamber and the heating water in the heat fluid transport pipe.

In the re-supply step, it is characterized in that the pressure of the heating water in the chamber is pressurized to be 5 to 25% higher than the pressure of the heating water in the heat fluid transport pipe.

According to the method for monitoring the water quality and corrosion characteristics of the thermal fluid transport pipe using the bypass of the present invention and the monitoring system using the same, the water quality and corrosion are considered in consideration of the elements optimized for the thermal fluid transport pipe, which is a moving passage of heating water, unlike the conventional method. By providing the characteristic monitoring method, there is an advantage that can significantly increase the accuracy of the measurement of the corrosion characteristics of the thermal fluid transport pipe according to the water quality.

In addition, by using a detour optimized for the heating water supply system, it is possible to connect the monitoring system directly, without interruption of the operating heat fluid transport pipe, can be easily applied to the actual environment, there is an economic advantage.

In addition, by optimizing the factors affecting the corrosion of the thermal fluid transport tube, it is possible to effectively grasp the corrosion characteristics of the thermal fluid transport pipe according to the water quality with a minimum number of sensors, as well as the corrosion of the thermal fluid transport pipe such as a three-electrode sensor. By deploying sensors that are effective in characterization, there is an advantage in that the corrosion characteristics can be measured quickly with minimal equipment.

1 is a flow chart sequentially showing a method of monitoring the water quality and corrosion characteristics of the thermal fluid transport pipe using the bypass according to the present invention
Figure 2 is a schematic diagram illustrating an embodiment of a water quality and corrosion characteristics monitoring system of the thermal fluid transport pipe using the bypass according to the present invention

Hereinafter, a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings with respect to the monitoring method and the water quality and corrosion characteristics of the thermal fluid transport pipe using the bypass according to the present invention. The present invention may be better understood by the following examples, which are for the purpose of illustrating the present invention and are not intended to limit the scope of protection defined by the appended claims.

First, the water quality and corrosion characteristics monitoring method of the thermal fluid transport pipe using the bypass of the present invention, as shown in Figure 1, extraction step (S10), water quality measurement step (S20), corrosion characteristic measurement step (S30), ash Characterized in that it comprises the input step (S40) and the analysis step (S50).

Extraction step (S10) is a step of extracting a part or all of the heating water in the heat fluid transport pipe, and put into the chamber. This is to extract and bypass the heating water inside the thermal fluid transport pipe for real time analysis.

Here, the thermal fluid transport pipe means a transport pipe for moving a fluid at a temperature higher than room temperature, and preferably means a transport pipe for heating water. In addition, heating water means the fluid used for heating.

In the extraction step (S10), it is preferable to extract in order to bypass some or all of the heating water flowing in the thermal fluid transport pipe, more preferably it is effective to extract a part of the heating water. This is because it is preferable to extract only some of the heating water rather than all of them in order to effectively grasp the water quality and corrosion characteristics of the heating water while minimizing the change of the thermal fluid transport system.

Here, the extraction amount is preferably 10 to 40% by volume, more preferably 20 to 30% by volume, most preferably 25% by volume, relative to 100% by volume of heating water flowing through the heat fluid transport pipe. . If less than 10% by volume, it is difficult to sufficiently analyze the corrosion characteristics, it is difficult to control the input amount, and when re-entry, high pressure must be applied, there is a problem that requires a lot of energy. In addition, if it exceeds 40% by volume there is a problem affecting the flow of the entire heat fluid transport system.

In addition, the extraction step (S10), due to the difference in the pressure of the heating water in the heat fluid transport pipe and the pressure of the chamber, it is preferable that the extraction of the heating water is made. That is, in order to minimize the influence on the thermal fluid transport system, it is effective to minimize the use of the valve and to extract the heating water only by the pressure difference.

The pressure difference is preferably 5 to 25% lower than the pressure of the heating water inside the heat fluid transport pipe, and more preferably 10 to 20% lower. If the pressure difference is less than 5%, there is a problem that a sufficient amount of heating water is difficult to be extracted within a predetermined time, and if it exceeds 25%, an excessive amount of heating water is extracted and there is a problem that it is difficult to control. That is, as a result of several experiments, it was confirmed that it is most effective to maintain the pressure difference of 5 to 25% compared with the extraction amount.

Next, the water quality measurement step (S20) is a step of measuring the water quality of the heating water in the chamber. This is to measure the water quality of the heating water, so as to effectively grasp the effect of the change in water quality on the corrosion of the specimen.

Here, the water quality measurement is measured by the heating water introduced into the chamber, which is measured as soon as it is extracted from the heat fluid transport pipe, and thus has the advantage of identifying the water quality on the entire heat fluid transport system in real time.

In addition, the water quality measurement step (S20), the water quality measurement of the heating water in the chamber, by installing a sensor that can measure at least one of dissolved oxygen, pH, electrical conductivity, flow rate or temperature in the chamber, in real time It is preferable to make, and more preferably, it is effective to install a sensor so that all of dissolved oxygen, pH, electrical conductivity, flow rate and temperature can be measured.

As a result of analyzing all the factors affecting the corrosion of the thermal fluid transport pipe, the heating water has been analyzed for the five corrosion factors optimized for the heating water, except for the factors that do not affect the accuracy of the corrosion rate measurement due to the minor effects. It is derived.

The effects of the five factors of water quality measurement on the corrosion degree are as follows.

First, in the case of pH, the heating system consists of various materials such as steel, copper, brass, stainless steel and plastic, so all materials must be considered for proper water treatment of heating water. Northern European countries recommend pretreatment of feed-water to maintain a pH of 9.8. For example, the solubility of magnetite is very low in a basic atmosphere of pH = 9 or higher, but in brass, the lowest corrosion rate is observed at pH = 9.5 and the corrosion rate is increased by elution of zinc at pH = 10, Has a large impact on corrosion in heating systems.

Next, in the case of dissolved oxygen and temperature, the carbon steel surface is covered with rust composed of two layers of Fe ₃ O ₄ and Fe ₂ O ₃ in neutral or alkaline water, and this rust layer inhibits iron dissolution and oxygen reduction reaction. In general, the water treatment standard of the heating system limits the dissolved oxygen concentration to 20 ppb or less, so that magnetite (Fe ₃ O ₄ ) is formed at the pH of the passivation region, and the magnetite is generally a dense and good protective film. Works. On the other hand, when more oxygen is introduced, the magnetite is oxidized to form hematite (Fe ₂ O ₃ ), which is weakly protected. The graph below shows the corrosion rate according to the dissolved oxygen concentration and temperature, and the corrosion rate of the steel pipe in the heating system, which is a closed circuit, increases as the dissolved oxygen concentration and temperature increase.

In the case of the ion concentration and the electrical conductivity, typically chloride ion (Cl ^-) and sulfate ions (SO ₄ ^2-) The higher the content of such corrosion resistant materials, and increase the corrosion rate of the metallic material, iron or copper ions crystalline Erosion erosion in the form of an oxide of or causes local corrosion through sedimentation / scale formation. In the case of circulating water, the electrical conductivity is limited to 1500 uS / cm or less, and when the ion concentration rises and the electrical conductivity of the solution increases, a larger area of the pipe acts as a cathode. May increase.

Finally, in the case of the flow rate, the corrosion rate of carbon steel, which is the main material of the thermal fluid transport pipe, is dominated by the dissolved oxygen diffusion rate on the surface of the steel, and as the flow rate increases, the corrosion rate of the steel increases. In the case of using a corrosion inhibitor, on the other hand, increasing the flow rate generally increases the diffusion rate of the corrosion inhibitor and thus shows a good anticorrosive effect. If the flow rate is low, the corrosion rate may be higher than that of no treatment if the concentration of the corrosion inhibitor is insufficient, and therefore, a sufficient amount of corrosion inhibitor should be added. In addition, proper flow rate control is required in consideration of fluid acceleration corrosion caused by dissolution or erosion of the protective coating (magnetite and water treatment agent) formed on the pipe surface.

Next, the corrosion characteristic measurement step (S30) is a step of measuring the corrosion characteristics of the specimen by immersing the specimen in the heating water in the chamber. This is a process for measuring in real time the corrosion characteristics of how the actual thermal fluid transport pipe is corroded by the heating water through the contact between the specimen and the heating water.

The specimen may be any material constituting the thermal fluid transport tube. Since the thermal fluid transport tube is made of various materials such as steel, copper, brass, stainless steel, and plastic, each material may be used as a specimen. In practice, it is most effective to use the material of the thermal fluid transport pipe as the specimen.

The installation position of the specimen may be any position as long as it can be sufficiently immersed in the heating water in the chamber.

Further, in the corrosion characteristic measurement step (S30), the corrosion characteristic measurement of the specimen, the calculation of at least one of the polarization resistance or the corrosion rate measured using a three-electrode sensor including a reference electrode, a working electrode and a counter electrode, It is preferable that the corrosion rate is calculated by using an electrical resistance sensor or the mass loss of the specimen is measured by at least one method, and more preferably, all three methods are effective in increasing accuracy.

The three-electrode sensor is composed of a reference electrode, a working electrode, and a counter electrode. The three-electrode sensor measures a corrosion degree according to a change in current and resistance, and can simultaneously measure polarization resistance and corrosion rate in real time.

In addition, the electrical resistance sensor, by measuring the electrical resistance increases as the cross-sectional area of the specimen through which the current passes, it is possible to measure the cumulative corrosion of the specimen and the corrosion rate over time in real time.

In addition, by measuring the mass of the specimen, the amount of mass reduction before and after corrosion can be periodically calculated to calculate the corrosion rate.

Next, the re-supply step (S40) is a step of injecting the heating water in the chamber back to the thermal fluid transport pipe. This is a process for minimizing the effect on the entire thermal fluid transport system by re-injecting the extracted heating water back to the thermal fluid transport system using the bypass.

In the re-supply step (S40), due to the pressure difference between the pressure of the heating water in the chamber and the pressure of the heating water inside the thermal fluid transport pipe, the heating water in the chamber is preferably introduced into the thermal fluid transport pipe. This is the same principle as the extraction step (S10), in order to minimize the impact on the entire thermal fluid transport system, it is to re-introduced using the pressure difference.

In the re-supply step (S40), it is preferable to pressurize the pressure of the heating water in the chamber to be 5 to 25% higher than the pressure of the heating water in the heat fluid transport pipe, more preferably 10 to 20%, most Preferably it is effective to press to 15% higher. If it is less than 5%, there is a problem that it is difficult to sufficiently enter the heating water into the heat fluid transport pipe, if it exceeds 25%, there is a problem that affects the entire heat fluid transport system with excessive pressure.

Finally, the analysis step (S50) is a step of analyzing the correlation between the water quality and the corrosion characteristics measured in the water quality measurement step and the corrosion characteristic measurement step in real time. This is not an essential step, but all of the corrosion characteristics according to the water quality can be measured in real time, and thus the correlation between them can be analyzed in real time. It is a process.

Next, the water quality and corrosion characteristics monitoring system of the thermal fluid transport pipe using the bypass according to the present invention, as shown in Figure 2, comprises an inlet 10, a connecting portion 20 and the discharge portion 30 It is characterized by. However, FIG. 2 is an embodiment, if the component is included, the configuration of the system may be variously modified.

The water quality and corrosion characteristic monitoring system of the thermal fluid transport pipe using the bypass of the present invention uses the water quality and corrosion property monitoring method of the heat fluid transport pipe using the bypass of the present invention. As mentioned in.

First, the inlet part 10 is connected to the heat fluid transport pipe 1, and extracts some or all of the heating water inside the heat fluid transport pipe. This is a bypass for extracting and analyzing the heating part of the thermal fluid transport pipe (1).

Next, the connection part 20 is a passage through which the heating water introduced into the inlet part 10 moves. It is connected to the inlet 10 and the outlet 30, serves as a passage for moving the heating water, and at the same time serves as a chamber for measuring the water quality and corrosion characteristics of the heating water and the specimen in the process of passing through it. do.

The connection part 20 is preferably provided with a specimen, a water quality sensor for measuring the water quality of the heating water, and a corrosion measurement sensor for measuring the corrosion characteristics of the specimen.

Here, the water quality measurement sensor, it is preferable to include at least one of dissolved oxygen measurement sensor, pH measurement sensor, electrical conductivity measurement sensor, flow rate measurement sensor or temperature measurement sensor. This is to select the optimum corrosion factor of the thermal fluid transport system and to install the sensor to measure it.

In addition, in the connecting portion 20, the corrosion measurement sensor, it is preferable that the mass measurement sensor, electrical resistance sensor or at least one of the three-electrode sensor including a reference electrode, a working electrode and a counter electrode. As mentioned above, this is a sensor necessary for measuring corrosion characteristics more accurately in real time.

Here, the mass measurement sensor measures the mass loss of the specimen, the electrical resistance sensor measures the change of the specific resistance of the specimen, the three-electrode sensor measures the corrosion rate by the polarization resistance and impedance spectroscopy method of the specimen It is desirable to.

Next, the discharge unit 30 is connected to the connecting portion 20, and serves to discharge the heating water introduced to the inlet 10 to the thermal fluid transport pipe (1). This is to enable the real-time analysis of the water quality and corrosion characteristics without influencing the entire thermal fluid transport system by introducing the heating water passed through the bypass back to the thermal fluid transport pipe (1).

The discharge unit 30 is preferably provided with a pump for increasing the discharge pressure of the heating water introduced into the inlet (10). By generating a pressure difference between the discharge portion 30 and the thermal fluid transport pipe 1, the heating water of the discharge part 30 is transferred to the thermal fluid transport pipe 1 without disturbing the flow of the thermal fluid transport pipe 1. In order to generate the optimum pressure difference for input into the pump, a pump is installed.

Finally, the valve 40 is installed at the inlet 10, the connection 20, and the outlet 30, respectively, and serves to control the heating water. Such a valve 40 is used to stop the operation of the bypass or to start, or to control the flow rate of the heating water.

In the above, the configuration of the present invention was described in detail with reference to one embodiment. However, the scope of the present invention is not limited to the above embodiment, and may be embodied in various forms of embodiments within the appended claims. Without departing from the gist of the invention as claimed in the claims, it is intended that such modifications can be made by anyone of ordinary skill in the art to be within the scope of the claims.

1: thermal fluid transport tube
10: inlet
20: Connection
30: discharge part
40: valve

Claims (14)

An extraction step of extracting some or all of the heating water inside the thermal fluid transport tube and inputting the same into the chamber;
A water quality measuring step of measuring the quality of the heating water in the chamber;
A corrosion characteristic measurement step of dipping the specimen in the heating water in the chamber to measure the corrosion characteristic of the specimen; And
Re-input step of re-injecting the heating water in the chamber into the heat fluid transport pipe; Method of monitoring the water quality and corrosion characteristics of the heat fluid transport pipe using a bypass, characterized in that it comprises a
The method of claim 1,
An analysis step of analyzing in real time the correlation between the water quality and the corrosion characteristics measured in the water quality measurement step and the corrosion characteristic measurement step; Water quality and corrosion characteristics monitoring method of the thermal fluid transport pipe using a bypass
The method of claim 1,
The extraction step, the method of monitoring the water quality and corrosion characteristics of the thermal fluid transport tube using a bypass, characterized in that the extraction of the heating water due to the pressure difference between the heating water in the heat fluid transport pipe and the pressure of the chamber.
The method of claim 3, wherein
In the extraction step, the water quality and corrosion characteristics monitoring method of the thermal fluid transport pipe using a bypass, characterized in that the pressure of the chamber is 5 to 25% lower than the pressure of the heating water in the heat fluid transport pipe.
The method of claim 1,
In the water quality measurement step, the water quality measurement of the heating water in the chamber is provided in real time by installing a sensor that can measure at least one of dissolved oxygen, pH, electrical conductivity, flow rate or temperature in the chamber. Monitoring Method of Water Quality and Corrosion Characteristics of Thermal Fluid Transport Pipe Using Bypass
The method of claim 1,
In the corrosion characteristic measurement step, the corrosion characteristic measurement of the specimen,
Calculation of at least one of polarization resistance or corrosion rate measured using a three-electrode sensor including a reference electrode, a working electrode and a counter electrode, calculation of corrosion rate using an electrical resistance sensor, or calculation of mass loss of the specimen to calculate corrosion rate Method for monitoring the water quality and corrosion characteristics of the thermal fluid transport pipe using a bypass, characterized in that made in at least one way
The method of claim 1,
The re-supply step, the heat using the bypass, characterized in that the heating water in the chamber is introduced into the thermal fluid transport pipe due to the pressure difference between the pressure of the heating water in the chamber and the pressure of the heating water in the heat fluid transport pipe. Monitoring method of water quality and corrosion characteristics of fluid transport pipe
8. The method of claim 7,
In the re-supply step, the water quality and corrosion characteristics of the thermal fluid transport pipe using the bypass, characterized in that the pressure of the heating water in the chamber is pressurized to be 5 to 25% higher than the pressure of the heating water in the heat fluid transport pipe. Monitoring method
An inlet connected to a heat fluid transport pipe and extracting part or all of the heating water inside the heat fluid transport pipe;
Connection portion that is a passage for moving the heating water introduced to the inlet; And
And a discharge part connected to the connection part and discharging the heating water introduced into the inlet part to the thermal fluid transport pipe.
The connection part, the water quality and corrosion characteristics monitoring system of the thermal fluid transport pipe using a bypass, characterized in that the specimen, a water quality sensor for measuring the water quality of the heating water and a corrosion measurement sensor for measuring the corrosion characteristics of the specimen is installed.
The method of claim 9,
The water quality and corrosion characteristics monitoring system of the thermal fluid transport pipe using the bypass, characterized in that the inlet, the connecting portion and the discharge portion includes a valve for controlling the heating water, respectively.
The method of claim 9,
The discharge unit, the water quality and corrosion characteristics monitoring system of the thermal fluid transport pipe using a bypass, characterized in that the pump is installed to increase the discharge pressure of the heating water introduced into the inlet portion
The method of claim 9,
In the connection portion, the water quality measurement sensor, water quality and corrosion of the thermal fluid transport pipe using a bypass circuit, characterized in that made of at least one of dissolved oxygen measuring sensor, pH measuring sensor, electrical conductivity measuring sensor, flow rate measuring sensor or temperature measuring sensor. Characteristic monitoring system
The method of claim 9,
In the connection portion, the corrosion measurement sensor, the water quality of the thermal fluid transport pipe using a bypass circuit, characterized in that made of at least one of a mass measurement sensor, an electrical resistance sensor or a three-electrode sensor including a reference electrode, a working electrode and a counter electrode. Corrosion property monitoring system
The method of claim 13,
The mass measuring sensor measures the mass loss of the specimen, the electrical resistance sensor measures the change of the specific resistance of the specimen, and the three-electrode sensor measures the corrosion rate by the polarization resistance and the impedance spectroscopy method of the specimen. Water quality and corrosion characteristic monitoring system of thermal fluid transport pipe using bypass

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