KR20120103000A - Eddy current test probe for transient zone of steam generator tubes in nuclear power plant and method for testing section change of transient zone with using thereon - Google Patents

Abstract

PURPOSE: An eddy current inspection probe and a method for inspecting transition region cross section change of a heat pipe using the same are provided to easily distinguish cross section change by forming an actual cross section of the heat pipe into graphics. CONSTITUTION: A probe body(11) comprises two or more coil mounting grooves(12) in a columnar direction. A front center apparatus(13) is formed on the shear of the probe body. A back center apparatus(14) is formed on the backend of the probe body. A coil is respectively mounted on the coil mounting groove. A steel wire(28) for fixation passes through the inner side of the probe body, the front center apparatus, and the back center apparatus and is fixed.

Description

Eddy current test probe for transient zone of steam generator tubes in nuclear power plant and method for testing section change of transient zone with using thereon}

The present invention relates to an eddy current test probe for cross section change inspection of a heat exchanger tube of a nuclear power plant steam generator and a method for inspecting a cross-sectional change of a transition region of a heat transfer tube using the same. The present invention relates to an eddy current test probe for cross-sectional change inspection of a heat transfer tube transition region of a nuclear power plant steam generator, and a method for inspecting the change of cross-section change of a heat transfer tube using such an eddy current test probe.

1 shows a schematic diagram of a reactor cooling system of a nuclear power plant, and FIG. 2 shows a detailed view of a transition zone of a steam generator heat pipe. As shown in FIG. 1, a reactor coolant system of a nuclear power plant includes a steam generator 1, a pressurizer 3, and a coolant pump 4 around a reactor 2. The coolant heated in the reactor 2 is supplied to the inlet of the heat transfer pipe 5 of the steam generator 1 by the coolant pump 4, and then heat transfer is performed in the heat transfer pipe 5. Cooling water supplied to the inlet of the heat pipe (5) is to transfer heat to the water supply of the turbine system flowing to the outside of the heat pipe (5). The coolant of the reactor 2 heated in the steam generator 1 exchanges heat to the water supply of the turbine system through the heat transfer surface of the heat transfer tube 5, and converts the water supply to steam outside the heat transfer tube 5.

2 shows a detailed view of the transition zone 7 of the steam generator heat pipe. The heat pipe 5 generally consists of a tube sheet 9, an expansion zone 8, a transition zone 7, and a heat pipe straight pipe 6. The tube sheet 9 serves to fix and support the start and end portions of the heat pipe 5, and generally has a thickness of about 21 inches, and the diameter of the hole into which the heat pipe 5 is inserted is larger than the diameter of the heat pipe 5. Is formed. In order to bring the heat transfer tube 5 into close contact with the hole of the tube sheet 9, the heat transfer tube 5 inserted in the tube sheet 9 is formed by an expansion method. Explosion expansion method and hydraulic expansion method are mainly used for this expansion method, and the primary cooling water (forming the flow path inside the heat transfer pipe) is welded between the end portion of the heat transfer pipe 5 and the tube sheet 9 so that the secondary cooling water ( Do not leak into the heat pipe external flow path). The expansion pipe is divided into an expansion pipe region 8 which is in close contact with the tube sheet 9, a straight pipe portion 6 of the heat transfer pipe, and a transition region 7 formed therebetween.

Steam generator (1) and heat pipe (5) is a core facility to ensure the operation safety of the nuclear power plant, the material of the heat generator tube (5) of the steam generator is generally inconel (corrosion resistant) to ensure the operation stability Is formed. However, as the operating life of the nuclear power plant increases, sludge and the like accumulate on the upper portion of the tube sheet 9, and as the sludge is fixed, a dent (cross section pressed without changing thickness in and out of the heat pipe) and the sludge is fixed. This results in cross-sectional changes, such as bulges (inflated cross-section without changing the thickness of the heat pipe in and out). In general, the portion where the cross-sectional change occurs is the transition region 7. In addition, the cross-sectional area changes may form cracks in the heat transfer tube due to the stress concentration phenomenon. Since the coolant of the nuclear reactor is likely to leak through such a crack, the cross-sectional state of the heat exchanger tube 5 of the steam generator is often inspected, and preventive maintenance work is performed to prevent leakage of the coolant.

Conventionally, the cross-sectional change was examined by using a rotary probe mainly for the eddy current inspection of the heat transfer tube transition zone of the steam generator. This rotary probe is applied to inspect defects such as cracks in the heat pipe 5, and it is possible to detect simple cross-sectional changes such as dents and bulges occurring in the transition zone of the heat pipe, but as shown in FIG. There was a problem that cannot be quantitatively measured. In addition, since the eddy current probe equipped with only one coil inspects the transition zone of the heat transfer tube, the eddy current detector had to measure the cross section of the heat transfer tube while rotating inside the heat transfer tube to check the sectional change in the circumferential direction of the heat transfer tube. The cross-sectional change inspection by the rotation probe according to the prior art has a slow inspection speed because the vertical movement in the axial direction of the heat pipe is performed while rotating in the circumferential direction of the heat pipe. There was a problem.

In addition, in order to inspect the cross-sectional change of the heat transfer tube transition zone of the steam generator, the cross-sectional change inspection by the bobbin probe was performed. As shown in Figure 3a, the cross-sectional change measurement of the cross-sectional change test by the bobbin probe according to the prior art can measure only the average diameter in the circumferential direction due to the eddy current formation characteristics of the bobbin probe, there is a problem that it is impossible to measure the size locally there was.

The present invention to solve the above problems, an object of the present invention is to improve the accuracy of the cross-sectional change inspection results of the heat pipe and increase the inspection speed, as well as improved nuclear power plant steam generator heat pipe for easy signal reading by the tester It is to provide an eddy current test probe to check the cross-sectional change occurring in the transition zone of the system.

In addition, another object of the present invention is to provide a method for inspecting the cross-sectional change of the transition region of the heat transfer tube to perform the cross-sectional change inspection of the transition region of the heat transfer tube accurately and in a short time using the eddy current test probe according to the present invention. .

In order to achieve the object of the present invention, the eddy current test probe for cross-sectional change inspection of the heat transfer tube transition zone of the nuclear power generator generator has a transducer body having two or more coil mounting grooves in the circumferential direction; A front centering device formed at a front end of the transducer body inserted into the transition region of the heat pipe; A rear centering device formed at a rear end of the transducer body; Coils respectively mounted in the coil mounting grooves; And a fixing steel wire fixed through the inside of the probe body and the front and rear centering devices to fix the transducer body and the front and rear centering devices.

In addition, in another preferred embodiment of the eddy current test probe according to the present invention, eight coil mounting grooves are arranged at an angle of 45 degrees along the circumferential direction of the transducer body.

Further, in another preferred embodiment of the eddy current test probe according to the present invention, the coil has a permeable iron core in the center, and is formed by winding a copper wire on the permeable iron core.

Further, in another preferred embodiment of the eddy current test probe according to the present invention, the front centering device is formed larger than the diameter of the straight pipe portion of the heat pipe, and the rear centering device is formed larger than the diameter of the transition zone of the heat pipe.

Further, in another preferred embodiment of the eddy current test probe according to the present invention, in order to prevent the eddy current test probe from moving in the circumferential direction of the heat pipe, the front and rear centering apparatus may be provided with one or more wings.

In addition, in another preferred embodiment of the eddy current test probe according to the present invention, the eddy current test probe is provided with an impedance adjustment with a variable capacitor, the variable capacitor to compensate for the difference in the electrical characteristics of the coil of each coil The same eddy current can be generated by adjusting the resonant frequency in the same way.

In order to achieve another object of the present invention, a method for inspecting a cross-sectional change occurring in a heat transfer tube transition region using an eddy current test probe may include moving the eddy current test probe to an inlet of a heat pipe by an eddy current test probe position adjusting device. ; Inserting the eddy current test probe into the heat transfer tube by an eddy current test probe transfer device; Generating an eddy current by the frequency generator; Inspecting the cross-sectional change of the transition region of the heat pipe by vertically moving the eddy current test probe by the drive computer; Transmitting a signal acquired through the cross-sectional change inspection step to a signal acquisition computer; And a three-dimensional graph of the cross-sectional change inspection result by the signal transmitted to the signal acquisition computer, and determining the cross-sectional change by quantitatively measuring the cross-sectional change of the transition region of the heat transfer pipe.

Eddy current test probe for inspecting cross-sectional change of transition zone of nuclear power plant steam generator heating tube according to the present invention and the transition zone cross-sectional change inspection method of the heat transfer pipe using the same is the cross-section of the transition zone of the heating pipe by a multi-coil eddy current test probe equipped with eight coils By inspecting the change, eight coils are arranged in the circumferential direction so that inspection can be performed only by vertical movement of the heat transfer tube in the axial direction without rotation of the transducer, and thus there is an effect that a quick cross-sectional inspection can be performed. In addition, by quantitatively measuring the magnitude of the cross-sectional change in the three-dimensional cross section, the actual cross section of the heat pipe can be graphically displayed, and the non-expert can easily determine the cross-sectional change by checking the graphical actual cross section. There is.

In addition, the eddy current test probe according to the present invention is provided with a front and rear centering device for preventing the eddy current test probe from shaking during the cross-sectional change inspection of the heat pipe, to prevent the eddy current test probe from shaking in the straight pipe and transition region of the heat pipe. By doing this, it is possible to perform an accurate cross-sectional inspection of the heat pipe. In addition, shortening the cross-sectional change inspection time of the heat transfer pipe has the effect of improving the utilization rate of the power plant, ensuring the safety of the nuclear power plant and reducing the cross-sectional change inspection cost.

1 shows a schematic diagram of a reactor cooling system of a nuclear power plant.
Figure 2 shows a detailed view of the transition zone of the steam generator heat pipe.
Figure 3a shows the cross-sectional change test results by the bobbin-type transducer.
Figure 3b shows the cross-sectional change test results by the rotary probe.
Figure 4 shows a perspective view of the eddy current test probe according to the present invention.
5 is an enlarged cross-sectional view of a coil mounted on an eddy current test probe according to a preferred embodiment of the present invention.
Figure 6a shows a cross-sectional view of the transducer body in the coil is mounted on the eddy current test transducer according to a preferred embodiment of the present invention.
6B shows a perspective view of the transducer body in a state where the coil is mounted in the coil mounting groove in the preferred embodiment of the present invention.
FIG. 6C shows a developed view in a state where the coil in FIG. 6B is mounted.
Figure 7 shows the front and rear centering device formed on the eddy current test probe according to a preferred embodiment of the present invention.
8A shows an eddy current test probe according to the present invention.
8B shows a variable capacitor provided in the impedance adjusting unit.
Figures 9a and 9b shows the results of the cross-sectional change test of the transition zone of the heat transfer tube using the eddy current test probe according to the present invention.
10 shows a schematic diagram of an apparatus for eddy current inspection of steam generator heat pipes.
Figure 11 shows a procedure for inspecting the transition zone of the heat pipe using the eddy current test probe according to the present invention.

Preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. First, in adding reference numerals to components of each drawing, the same components are designated by the same reference numerals.

4 is a perspective view of the eddy current test probe 10 according to the present invention. The eddy current test probe 10 according to the present invention includes a transducer body 11, a front centering device 13, a rear centering device 14, a coil 15, and a fixing steel wire 28. The transducer body 11 has two or more coil mounting grooves 12 in the circumferential direction, and the coil 15 is mounted on the coil mounting groove 12. The front centering device 13 is formed at the front end of the transducer body 11. When the heat transfer tube 5 is inserted, the front centering device 13 is first inserted into the heat transfer tube 5. In addition, a rear centering device 14 is formed at the rear end of the transducer body 11 to face the front centering device 13. A fixing steel wire 28 is installed to penetrate the inside of each of them to fix the transducer body 11 and the front and rear centering devices 13 and 14. By fixing the fixing steel wire 28, the eddy current inspection probe 10 is prevented from being separated even during the cross-sectional change inspection. Preferably, the fixing steel wire 28 may be formed of a stainless material to maintain sufficient strength.

5 is an enlarged cross-sectional view of the coil 15 mounted to the eddy current test probe 10 according to the preferred embodiment of the present invention. The coil 15 has a permeable iron core 16 at the center, and is formed by winding a copper wire on the permeable iron core 16. When current flows through the coil 15 into which the permeable iron core 16 is inserted, the impedance can be increased, so that the number of turns of the winding can be reduced. Accordingly, the overall volume and size of the coil 15 can be reduced.

6A is a cross-sectional view of the transducer body 11 in a state in which the coil 15 is mounted on the eddy current inspection transducer 10 according to the preferred embodiment of the present invention. FIG. 6B shows a perspective view of the transducer body 11 with the coil 15 mounted in the coil mounting groove 12 in a preferred embodiment of the invention, and FIG. 6C shows that the coil 15 in FIG. The developed view in the attached state is shown. Although not necessarily limited thereto, in the preferred embodiment of the present invention, eight coil mounting grooves 12 are disposed at a 45 degree angle along the circumferential direction of the transducer body 11. The eight coil mounting grooves 12 are mounted with coils 15 wound to a predetermined size and number of turns. In order to prevent a change in impedance, the coil 15 is preferably bonded to the coil mounting groove 12 with an epoxy adhesive. Accordingly, when the eddy current test probe 10 according to the present invention examines the cross-sectional change in the heat transfer pipe 5, the cross-sectional change of the heat transfer pipe 5 can be inspected only by vertical movement in the axial direction of the heat transfer pipe 5 without rotation. The inspection time can be shortened.

7 shows the front and rear centering devices 13 and 14 formed in the eddy current test probe 10 according to the preferred embodiment of the present invention. The front centering device 13 is formed slightly larger than the diameter of the heat pipe straight pipe 6. Although not necessarily limited to this, it is preferable that the diameter of the front centering device 13 is formed to be about 0.2 mm larger than the diameter of the heat pipe straight pipe 6. The rear centering device 14 is formed larger than the diameter of the transition region 7 of the heat transfer tube so as to support the transition region 7 formed in the expansion region 8 during the cross-sectional change inspection. Preferably, since the diameter of the expansion region 8 is generally about 0.2 mm, the rear centering device 14 is formed to be about 0.2 mm larger than the front centering device 13. Further, in order to prevent the eddy current test probe 10 from moving in the circumferential direction of the heat pipe 5, the front and rear centering devices 13 and 14 are provided with one or more vanes 17. Although not necessarily limited thereto, preferably, the front and rear centering devices 13 and 14 deteriorate the accuracy and reliability of the cross-sectional change inspection when the blades 17 are broken during the inspection, and the broken pieces of the steam generator 1 It is provided with six wings 17 which can exist as foreign matter in the) to maintain sufficient elasticity and strength. Accordingly, the eddy current test probe 10 is tightly adhered to the heat transfer pipe 5, thereby preventing the eddy current test probe 10 from shaking during the test, thereby improving the accuracy of the cross-sectional change test.

8A shows the eddy current test probe 10 according to the present invention, and FIG. 8B shows the variable capacitor 30 provided in the impedance adjusting box 29. The eddy current test probe 10 according to the present invention includes an impedance adjusting box 29 having a variable capacitor 30, and the variable capacitor 30 includes eight coils each mounted in the coil mounting groove 12. The same eddy current can be generated by compensating for the difference in electrical characteristics of 15) by equally adjusting the resonance frequency (impedance) of each coil 15.

9A and 9B show the results of cross-sectional change inspection of the transition region 7 of the heat pipe using the eddy current test probe 10 according to the present invention. In FIG. 9A, the cross-sectional view of the normal expansion region of the heat transfer pipe 5 shows a circular shape in which the eight coils 15 detect a constant distance in the circumferential direction. The minimum diameter, the maximum diameter, and the average diameter of the heat exchanger tube 5 can be known by the figure 24 and the dimensional display window 25. FIG. 9B shows the shape 26 of the three-dimensional inspection result of the cross-sectional change in the state where the dent has occurred in the transition region 7 of the heat transfer tube. In FIG. 9B, the site where the dents are formed is pressed in to show an ellipse. That is, the eddy current test probe 10 according to the present invention can monitor the accurate test values quantitatively in three dimensions as compared with the prior art, and non-experts can easily analyze the test results, thereby reducing the test time and cost. The effect can be reduced.

Fig. 10 shows a schematic diagram of an apparatus for eddy current inspection of the steam generator heat pipe 5, and Fig. 11 shows a procedure diagram for inspecting the transition region 7 of the heat pipe using the eddy current test probe 10 according to the present invention. An apparatus for eddy current inspection is composed of an eddy current inspection transducer position adjusting device 22, an eddy current inspection transducer transporting device 21, a frequency generator 18, a drive computer 20, and a signal acquisition computer 19. In addition, the method for inspecting the cross-sectional change occurring in the heat transfer tube transition region (7) using the eddy current test probe 10 includes the eddy current test probe moving step (S1), the eddy current test probe insertion step (S2), the eddy current generating step ( S3), the cross-sectional change inspection step (S4) of the transition region, the step of transmitting a signal to the signal acquisition computer (S5), and the step of determining the cross-sectional change (S6). The device for eddy current inspection of the heat transfer tube 5 is driven by a drive computer 20 programmed to drive the signal acquisition computer 19 and the eddy current inspection probe position adjusting device 22. The drive computer is driven to move the eddy current test probe 10 to the inlet of the heat transfer pipe 5 by the eddy current test probe position adjusting device 22. After this eddy current test probe moving step (S1), the eddy current test probe 10 is inserted into the heat transfer pipe 5 by the eddy current test probe transfer device 21. After the eddy current test probe insertion step S2, the frequency generator 18 is driven to compensate for the difference in electrical characteristics of the eight coils 15 with the variable capacitor 15 to generate the same eddy current. After the eddy current generation step S3, the eddy current test probe 10 is moved vertically with respect to the axial direction of the heat pipe 5, that is, the heat pipe 5 by the drive computer 20, so that The cross-sectional change is examined. Eight coils 15 are mounted in the coil mounting groove 12, so that the eddy current test probe 10 does not rotate inside the heat pipe 5, and changes the cross section in the transition region 7 of the heat pipe by vertical movement. You will be able to inspect quickly. When the eddy current inspection transducer 10 moves, a current of a specific frequency applied by the frequency generating device 18 passes through the coil 15 to form an induction current in the heat pipe 5, and an eddy current due to the induced current is generated. This eddy current causes an impedance change in the coil 15 of the eddy current test probe 10 along the cross section of the heat pipe 5. This impedance change is converted into a digital signal in the eddy current frequency generator 18 to appear on the computer screen. The signal acquired through the cross-sectional change inspection step S4 is transmitted to the signal acquisition computer 19. Through the signal transmitted to the signal acquisition computer 19 by the step of transmitting the signal (3) to the cross-sectional change inspection results so that even non-experts can easily analyze, and the three-dimensional graph of the transition region of the heat pipe The result of the cross-sectional change is measured quantitatively to determine the cross-sectional change. Therefore, by checking the cross-sectional change inspection in the transition region (7) of the heat exchanger tube by the accurate cross-sectional change inspection result and quantitative numerical value, it is possible to accurately predict or perform the repair time of the heat exchanger tube, to ensure the stability of the nuclear power plant and to maintain operating costs. You can save.

The invention is not limited to the variants shown in the drawings, but may be extended to other embodiments that fall within the scope of the appended claims.

1: steam generator, 2: reactor,
3: pressurizer, 4: coolant pump,
5: heat pipe, 6: heat pipe straight pipe,
7: transition area, 8: expansion area,
9: tube sheet, 10: eddy current test probe,
11: transducer body, 12: coil mounting groove,
13: front centering device, 14: rear centering device,
15: coil, 16: permeable iron core,
17 wing, 18 frequency generator,
19: signal acquisition computer,
20: drive computer,
21: eddy current inspection transducer transfer device,
22: eddy current inspection transducer position adjusting device,
23: 3D inspection result shape, 24: cross-sectional inspection result shape,
25: regular dimension display window,
26: 3D inspection result shape of the dent occurrence,
27: signal transmission cable, 28: fixing steel wire,
29: impedance adjuster, 30: variable capacitor,
S1: moving step of the eddy current test probe,
S2: insertion step of the eddy current test probe,
S3: eddy current generation step,
S4: cross-sectional change inspection step of the transition region,
S5: transmitting a signal to a signal acquisition computer,
S6: Step of determining the cross-sectional change.

Claims (8)

In the eddy current inspection probe for inspecting the cross-sectional change occurring in the transition region (7) of the heat transfer pipe,
A transducer body (11) having two or more coil mounting grooves (12) in the circumferential direction;
A front centering device (13) formed at the front end of the transducer body (11) inserted into the transition zone (7) of the heat pipe;
A rear centering device (14) formed at the rear end of the transducer body (11);
Coils 15 mounted to the coil mounting grooves 12, respectively; And
Fixing steel wires fixed through the inside of the transducer body 11 and the front and rear centering devices 13 and 14 to fix the transducer body 11 and the front and rear centering devices 13 and 14 ( 28) Eddy current test probe for cross-sectional change inspection of heat transfer tube transition zone of nuclear power plant steam generator.
The eddy current test of the heat transfer tube transition zone cross section of the nuclear power plant steam generator according to claim 1, characterized in that eight coil mounting grooves (12) are arranged at a 45 degree angle along the circumferential direction of the transducer body (11). Transducer.
3. The cross section change of the heat transfer tube transition region of the nuclear steam generator according to claim 2, wherein the coil (15) has a permeable iron core (16) at its center and is formed by winding a copper wire on the permeable iron core (16). Eddy current probe for inspection.
4. The eddy current test probe according to claim 3, wherein the front centering device (13) is formed larger than the diameter of the straight pipe portion (6) of the heat transfer pipe.
5. The eddy current test probe according to claim 4, characterized in that the rear centering device (14) is formed larger than the diameter of the transition zone (7) of the heat transfer tube.
The method of claim 5, wherein the front and rear centering device (13, 14) is provided with one or more blades (17), in order to prevent the eddy current test probe 10 to move in the circumferential direction of the heat pipe (5). An eddy current test probe for cross-sectional change inspection of heat transfer pipe transition zone of a nuclear power plant steam generator.
The method of claim 6, wherein the eddy current test probe 10 is provided with an impedance adjusting box 29 is provided with a variable capacitor (30), the variable capacitor 30 is the difference in the electrical characteristics of the coil (15) An eddy current test probe for cross-sectional change inspection of a heat transfer tube transition region of a nuclear power plant steam generator, characterized in that to generate the same eddy current by compensating the resonance frequency of each coil 15 equally.
A method for inspecting the cross-sectional change occurring in the heat transfer tube transition region (7) by using the eddy current test probe (10) according to any one of claims 1 to 7,
Moving the eddy current inspection probe 10 to the inlet of the heat transfer pipe 5 by the eddy current inspection probe position adjusting device (S1);
Inserting the eddy current test probe (10) into the heat transfer pipe (5) by the eddy current test probe transporting device (21) (S2);
Generating an eddy current by the frequency generator 18 (S3);
Inspecting the cross-sectional change of the transition region 7 of the heat transfer tube by vertically moving the eddy current test probe 10 by the drive computer 20 (S4);
Transmitting a signal acquired through the cross-sectional change inspection step (S4) to a signal acquisition computer (19) (S5); And
And a step (S6) of determining the cross-sectional change by quantifying the cross-sectional change inspection result by the signal transmitted to the signal acquisition computer 19, and quantitatively measuring the cross-sectional change of the transition region 7 of the heat transfer pipe. Method for inspecting the cross-sectional change occurring in the heat transfer tube transition region (7) by using the eddy current test probe (10) characterized in that.

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