KR20100044504A - An analysis method for the flow blockage rate at the heat exchanger tube support plate using eddy current signal - Google Patents

Abstract

PURPOSE: A method for evaluating the blockage rate of a passage groove of a tube support plate of a heat transferring tube by using an eddy current signal is provided to grasp the blockage rate of a passage groove of a tube support plate by comparing signals of a rotary probe and the signals of a bobbin probe. CONSTITUTION: A method for evaluating the blockage rate of a passage groove of a tube support plate of a heat transferring tube by using an eddy current signal comprises following steps. The blockage rate of a passage groove of a tube support plate is measured using signals of the rotary probe for the eddy current inspection of the heat pipe about the tube support plate of the vertical heat exchanger(1). The signal size of the bobbin probe is measured on a selected heat pipe(2). Correlation between the blockage rate of a passage groove of a tube support plate and the signal size of the bobbin probe is calculated(3). The signal size of the bobbin probe is converted into the blockage rate of the passage groove of the tube support plate of the heat exchanger using the correlation(4).

Description

An Analysis Method for the Flow Blockage Rate at the Heat Exchanger Tube Support Plate Using Eddy Current Signal}

The present invention relates to a method for evaluating the degree of blockage of the tube support plate flow path groove of a heat transfer tube using an eddy current signal. The present invention relates to a method for evaluating the degree of blockage of grooves in the tube support plate of a heat transfer pipe using an eddy current signal that can be measured.

Vertical heat exchanger consists of a large number of heat pipes through which high temperature water flows, and heat exchange of water supplied to the outside of the heat pipes, and each heat pipe is fixed to the tube plate, and the tube support plate maintains the gap in the longitudinal direction. .

The tube support plate is arranged several times at regular intervals along the length of the heat transfer tube to support the heat transfer tube. Outside the heat pipe of the heat exchanger, oxidative deposits accumulate in the congestion path as the number of operating years increases, and it hardens over time. In particular, oxidized deposits are accumulated in the upper grooves of the tube plates or the tube support plates, and the hardened deposits accumulated in the channel grooves block the channel grooves.

Therefore, the degree of clogging of the flow path groove of the pipe support plate is periodically measured. In the past, a remotely controlled camera is inserted into the heat exchanger to monitor and this visual inspection is limited to the internal structure of the heat exchanger. There is an inaccessible area, and there is a problem that a blind spot exists depending on the camera approach angle.

An object of the present invention is derived to solve the conventional problems as described above, the eddy current signal according to the degree of clogging the flow path groove in the tube support plate by using the bobbin probe signal and the rotary probe signal to perform the eddy current test of the heat exchanger The present invention provides a method for evaluating the degree of blockage of the pipe support plate flow path of a heat transfer tube using an eddy current signal capable of estimating the degree of change and the degree of blockage of the flow path groove of the pipe support plate of the entire heat exchanger.

In order to achieve the above object, the method of evaluating the degree of blockage of the tube support plate flow path groove of the heat transfer tube using the eddy current signal according to the present invention uses a signal of the rotary probe for eddy current inspection of the heat transfer tube with respect to the four leaf tube support plate of the vertical heat exchanger. A first step of measuring the flow path groove blocking degree; A second step of measuring a signal magnitude of the bobbin probe with respect to the selected heat pipe; A third step of obtaining a correlation between the flow path groove blockage degree by the signal of the rotary probe obtained in the first step and the second step and the signal size of the bobbin probe; And a fourth step of evaluating the signal magnitude of the bobbin probe with respect to the tube support plates of the entire heat exchanger in terms of the degree of blockage of the grooves of the tube support plate flow passages of the entire heat exchanger using the correlation equation obtained in the third step.

The signal of the rotary probe of the first step increases as the amount of deposit blocking the flow path groove increases.

The signal of the bobbin probe of the second step increases as the amount of deposits blocking the flow path grooves increases.

The correlation in the third step is obtained by placing the degree of blockage by the rotatable transducer on the vertical axis, drawing the point by placing the signal magnitude by the bobbin transducer on the horizontal axis, and obtaining a correlation by linearly approximating each point. .

As described above, the method for evaluating the degree of blockage of the pipe support plate flow path grooves of the heat transfer tube using the eddy current signal according to the present invention can grasp the degree of blockage of the flow path of the four-leaf tube support plate of the vertical heat exchanger.

Fundamentally, the heat exchanger performs periodic nondestructive testing, and as a basic inspection, defect evaluation is performed using the eddy current signal of the bobbin transducer. Therefore, by adding only the signal of the rotary probe to the tube support plate of a few heat pipes can be compared with the signal of the bobbin probe that is already performed to determine the degree of blockage of the flow path of the tube support plate.

If the flow path blockage is severe, abnormalities may occur in the flow of the water supply to the outer surface of the heat pipe, which may cause heat exchanger level instability, and corrosion defects may occur due to deposits. Therefore, it is possible to grasp the trend through periodic flow rate blockage evaluation, and to provide a means to manage below a certain amount by cleaning the heat exchanger if a certain amount is blocked.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings such that those skilled in the art may easily implement the present invention.

1 is a partially cutaway perspective view of a vertical heat exchanger.

As shown in FIG. 1, the vertical heat exchanger is coupled to the plurality of heat exchanger tubes 10 installed at a predetermined interval while standing in the vertical direction, and is coupled at a predetermined interval in the longitudinal direction of the heat exchanger tube 10. It comprises a plurality of tube support plate 20 to prevent the shaking of the tube plate 30 coupled to the lower end of the heat transfer tube (10).

Here, since the vertical heat exchanger is already well known to those skilled in the art, a description of the structure and principle will be omitted.

Figure 2 is a perspective view of the transducer used in the heat exchanger eddy current inspection.

As shown in FIG. 2, the transducer used in the present invention includes a bobbin transducer 40 and a rotary transducer 41. Here, since the bobbin transducer 40 and the rotary transducer 41 are also well known to those skilled in the art, the description of the structure and principle will be omitted.

3 is a view showing the clogging phenomenon between the heat transfer tube and the four leaf tube support plate.

As shown in FIG. 3, the flow path groove blockage 50 of the tube support plate 20 in the heat exchanger means a phenomenon in which the flow path groove is blocked between the heat transfer tube 10 and the pipe support plate 20. For this purpose, the signal of the bobbin probe for eddy current inspection and the signal of the rotary probe are used.

4 is a flowchart illustrating a procedure of an eddy current signal evaluation method according to clogging a flow path groove.

As shown in FIG. 4, the method for evaluating the degree of blockage of the groove of the tube support plate flow path using the eddy current signal includes a rotary probe signal evaluating step (first step, 1), a bobbin probe signal measuring step (second step, 2), and , The correlation derivation steps (third and third steps), and the degree of passage blockage evaluation steps (fourth and fourth steps).

Hereinafter, the eddy current signal evaluation method according to the blocking of the flow path groove according to the present invention will be described in detail with reference to FIGS. 5 to 7.

The first step (1) is an evaluation of the signal of the rotary probe for several selected heat pipes. The signal of the rotatable transducer is clearly visible in the shape of approximately four fingers, as shown in Fig. 5, where the four parts contacting the support plate at low frequency (approximately 20 kHz). If the flow groove is blocked, the sediment signal appears in the four bones, and the higher the amount of sediment, the higher the height. The flow path blockage according to the height is expressed as follows. The degree of blockage of the flow path B of the pipe support plate is an average value of the degree of blockage of the flow paths B1, B2, B3, and B4 of each valley.

The larger the signal size of each valley, the more the channel grooves are blocked.The signal amplitude reaching approximately 90% of the adjacent peak signal is 100% blocked signal amplitude (V100), and the clear bone signal amplitude is 0% blocked signal amplitude. As (V0), the degree of blockage (B1, B2, B3, B4) of each valley can be calculated as follows.

The evaluation using the signal of the bobbin probe on the tube support plate of the heat transfer tube passed through the first step (1) is performed as the second step (2) below.

The second step (2) is the evaluation of the bobbin transducer signal for several selected heat pipes. The bobbin transducer signal is in contact with the support plate at low frequencies (approximately 100 kHz) and thus has a typical approximately "b" shape as shown in FIG. 6A. If the flow path groove is blocked, this shape is distorted, as shown in FIG. 6B. As the amount of the deposit increases, the degree increases, and the distorted signal size H1 increases, and the distortion signal size H1 is measured. . As the degree of flow path groove blockage increases, the distorted bobbin transducer signal has a proportional relationship as shown in FIG. 6C. Since this proportional relationship may be different due to the difference in conductivity due to the sediment component of the heat exchanger, the degree of passage blockage is obtained through the relationship with the rotary probe signal through the third step (3) below.

In the third step (3), the signal evaluation result of the bobbin probe obtained in the second step is obtained by measuring the blockage of the flow path of the rotary probe obtained in the first step (1) for several heat pipes, as shown in FIG. Draw a point on the horizontal axis, and linearly approximate each point to find the equation. In Fig. 7, for example, the equation y = 7.715x-16.9 is derived.

The fourth step (4) evaluates the bobbin probe signal for the tube support plate of the entire heat exchanger, and clogs the flow path grooves of the tube support plate of the entire heat exchanger using the correlation equation obtained from the third step (3). Evaluate in terms of degree.

In this way, the flow path blockage evaluation using a conventional visual inspection camera is a qualitative evaluation by the evaluator, whereas the method according to the present invention enables quantitative evaluation by an eddy current signal, and has a blind spot and an access limit due to the internal structure of the heat exchanger. It is possible to evaluate the entire tube support plate of the heat pipe because it does not exist, and it can be evaluated by using the characteristics of the transducer signal required for the existing soundness evaluation which is periodically conducted.

In addition, the use of the method of the present invention does not require additional equipment in addition to the existing soundness evaluation equipment, and does not require additional air according to the installation, the existing non-destructive inspector can immediately confirm the result through the evaluation using the method of the present invention, Periodic evaluation can identify trends of blockage by cycle and can be used directly for heat exchanger management.

In addition, since the non-destructive inspection for the periodic integrity evaluation of the heat exchanger is continuously performed during the heat exchanger life, the method of the present invention utilizing the signal of the basic inspection technique can be applied throughout the life of the heat exchanger, the cycle by cycle according to the heat exchanger It can be used continuously to identify blockages.

In addition, the non-destructive evaluator of the heat exchanger tube of the existing heat exchanger may evaluate the degree of passage blockage using the method of the present invention, and the heat exchanger passage blockage evaluation result may be easily recognized for each position by converting it into a numerical value or a color.

In addition, it can be used in all processes that use vertical heat exchangers in the process, including thermal power and nuclear power, and can be applied where water level / flow control of heat exchangers is required and periodical health assessment is required.

In addition, as the service life of the heat exchanger increases, there is no need for additional equipment where there is concern about erosion and water level fluctuations due to deposits on the tube support plate of the heat exchanger. The result can be quantitatively confirmed, contributing to the long-term management of the heat exchanger.

In addition, there is no need for a separate additional equipment, etc. where applicable, and the entry barrier is very low compared to other techniques because it is easy to process the result quantitatively.

What has been described above is only one embodiment for carrying out the method for evaluating the degree of blockage of the groove of the tube support plate flow path of the heat transfer tube using the eddy current signal according to the present invention, the present invention is not limited to the above-described embodiment, the following claims As claimed in the scope of the present invention, those skilled in the art to which the present invention pertains will have the technical spirit of the present invention to the extent that various modifications can be made.

1 is a partially cutaway perspective view of a vertical heat exchanger.

2 is a perspective view of a transducer used for heat exchanger eddy current inspection.

3 is a view showing a blockage phenomenon between the heat transfer pipe and the four leaf-shaped tube support plate.

4 is a flowchart illustrating a procedure of an eddy current signal evaluation method according to clogging a flow path groove.

5 is a diagram illustrating the evaluation of the rotary probe signal of the first step.

6a to 6c is a view showing the signal measurement of the bobbin transducer,

Figure 6a shows the bobbin transducer signal without passage blockage,

6b shows the bobbin transducer signal distorted by the flow path blockage,

6C shows the proportional relationship between the distorted bobbin probe signal and the flow path blockage.

7 is a diagram for deriving a correlation equation of a third step.

<Description of Symbols for Main Parts of Drawings>

10: heat pipe 20: tube support plate

30: tube sheet 40: bobbin transducer

41: rotary probe 50: clogged euro groove

Claims (4)

A first step of measuring the degree of clogging of the flow path grooves by using a signal of a rotary probe for eddy current inspection of the heat transfer tube with respect to the four-leaf tube support plate of the vertical heat exchanger; A second step of measuring a signal magnitude of the bobbin probe with respect to the selected heat pipe; A third step of obtaining a correlation between the flow path groove blockage degree by the signal of the rotary probe obtained in the first step and the second step and the signal size of the bobbin probe; And, Using the eddy current signal comprising a fourth step of evaluating the signal magnitude of the bobbin transducer for the tube support plate of the entire heat exchanger in terms of the degree of blockage of the grooves in the flow path of the tube support plate of the heat exchanger using the correlation equation obtained in the third step. Method for evaluating the degree of blockage of the flow path of the tube support plate of the heat pipe. The method of claim 1, The method of evaluating the degree of blockage of the pipe support plate flow path groove of the heat transfer tube using the eddy current signal, characterized in that the signal of the rotary probe of the first step is increased as the amount of the deposit blocking the flow path groove increases. The method of claim 1, The signal of the bobbin probe of the second step is higher as the amount of deposits blocking the flow path grooves is increased. The method of claim 1, Correlation in the third step is made by obtaining the correlation by positioning the degree of blockage by the rotary transducer on the vertical axis, drawing the points by placing the signal magnitude by the bobbin transducer on the horizontal axis, and then linearly approximating each point. Method for evaluating the blockage of the groove of the tube support plate flow path of the heat transfer tube using the eddy current signal.

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