KR20130006006A - Eddy current probe - Google Patents

Abstract

PURPOSE: An eddy current probe is provided to set an eddy current inspecting direction according to a defect direction and to vertically place the eddy current probe on a geometrical defect surface, thereby improving the capacity and the reliability of an inspection. CONSTITUTION: An eddy current probe comprises a body unit(100) and a supporter(200). A cylindrical internal space is formed in the inside of the body unit. The probe composed of differential coils is protruded in the front surface of the supporter and mounted to be rotated around the body unit. An attachable/detachable probe tip(300) is arranged in the front side of the supporter. A through-hole(301) is formed in the central part of the probe tip in order that the probe can be inserted and protruded to the outside.

Description

Eddy current probe

The present invention relates to an eddy current probe, and in particular, by rotating the probe of the comparative coil array to check perpendicular to the direction of the defect to improve the defect detection ability, and to provide a probe tip of various shapes to suit the shape of the inspection site The invention relates to an eddy current probe, which in turn makes it possible to position the probe perpendicular to the mating surface of the geometry, thereby improving the reliability of the inspection.

In general, Eddy Current Testing is one of non-destructive testing methods applied to the detection of surface defects in aircraft, power generation facilities, and other industrial facilities, and the integrity inspection of heat exchangers.

At this time, the principle of the eddy current test, as shown in Figure 1, when passing the alternating current through the coil, the primary magnetic field is generated around, and when it approaches the conductor (subject) surface, the secondary magnetic field is formed on the conductor surface, The secondary magnetic field again generates eddy currents (eddy currents) on the conductor surface. If the eddy currents are distorted when there is a defect on the conductor surface, this is displayed on the Impedance Plan through the sensor coil and analyzed and evaluated. That's how.

The main advantage of this eddy current inspection is not only excellent detection ability (finding defects) such as surface microdefects, but also quantitative evaluation (defect depth) through comparative comparative specimens As a result, it is increasingly being used for facility diagnosis in various industries.

In power generation, stress (fatigue cracks) during operation such as airfoils, leading and trailing edges, dovetails and wheel grooves of turbine rotors Precise diagnosis is performed by using the eddy current test on the frequently generated parts.

In addition, the wheel groove of the gas turbine rotor rotor generally has the shape of a fir-tree type in the power generation field, and the airfoil of the blade has a concave shape of a concave and a convex of a convex. The shape has a twisted shape due to the aerodynamic structure.

As a result, a typical pencil-type surface probe cannot be accurately examined due to the geometric shape of the subject during eddy current inspection, and a defect is generally observed when the component and the eddy current probe to be examined are vertically examined. Excellent detectability for.

However, in the related art, a phenomenon in which an eddy current signal is influenced by an edge of a test object as shown in FIG. 2 due to the geometry of the test object (Edge Effect, a), and the probe swinging from side to side (Tilting) , b), local lifting (Lift-off, c), etc., may have an effect on the eddy current test, resulting in an unwanted signal or an improper effect on the test due to an impedance value different from the actual defect and magnitude. .

In addition, the eddy current affects the detection sensitivity of the defect according to the direction of the defect and the inspection direction of the probe. As shown in FIGS. 3 and 4, the eddy current perpendicular to the defect is excellent in the detection sensitivity and is clearly visible on the impedance plane. Although it appears as a signal (Sharp), when the parallel to the defect there is a problem that no signal appears on the impedance plane or the detection sensitivity is reduced.

The present invention relates to an eddy current probe to solve the above problems, and in particular, by rotating the probe of the comparative coil array to be perpendicular to the direction of the defect to improve the defect detection ability, to suit the shape of the inspection site The purpose of the present invention is to improve the reliability of inspection by replacing probe tips of various shapes so that the probes can be positioned perpendicular to the mating surfaces of the geometric shapes.

The present invention and the body portion is formed in the inner cylindrical space; Probes made of differential coils protrude forward and are achieved by including a support that is rotatably mounted relative to the body portion.

In addition, the front of the support is provided with a removable probe tip, it is preferable that the through-hole is formed in the center of the probe tip so that the probe is inserted to protrude to the outside.

In addition, a guide hole for guiding the rotation direction of the support is formed in the outer surface of the body portion, a first insertion groove is formed in the outer peripheral surface of the support, the first insertion groove through the guide hole in the outer body portion It is desirable to have a fastening member to be fastened to.

In addition, the front surface of the probe tip is preferably made to be a shape corresponding to the surface to be inspected.

In addition, a second insertion groove is formed on the outer surface of the body portion, it is preferable that the handle is mounted in the vertical direction to the second insertion groove.

In addition, the lower portion of the handle is provided with a connector is interlocked with the eddy current test device, the connector is preferably connected to the probe of the support.

In addition, the body portion is penetrated through the support, it is preferable that the fixing cap is inserted into the support end so that the body portion is assembled between the support and the fixing cap.

The present invention as described above is an invention that is effective in improving the inspection ability and the inspection reliability by being able to match the eddy current inspection direction according to the defect direction, and to be perpendicular to the defect surface of the geometric shape.

1 is a diagram showing a general eddy current flow;
2 is a diagram showing a geometric influence factor of a general eddy current test;
3 is a diagram showing a detection capability of an eddy current test according to a defect direction of a test object conventionally;
4 is a diagram showing a case where the direction of the object under test and the eddy current are parallel and a case where the direction of the object under test and the eddy current are vertical;
5 is an exploded perspective view showing an eddy current probe of the present invention;
6 shows a probe tip of the eddy current probe of the present invention;
7 shows an eddy current probe of the present invention;
8 and 9 illustrate an embodiment of the eddy current probe of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

In the eddy current probe of the present invention, as shown in FIGS. 5 to 9, a support 200 including a probe 201 is rotatably mounted to a pipe-shaped body 100, and an end of the probe 201 is provided. Through the probe tip 300 mounted on the front surface of the support 200 to enable the eddy current inspection on the surface of the object through the probe 201 to improve the inspection performance on the surface of the geometric object. It is a basic technical feature.

Hereinafter, each component of the eddy current probe of the present invention will be described with reference to the accompanying drawings.

First, as shown in FIG. 5, one end of the support 200 including the probe 201 is inserted into the body 100 having a cylindrical inner space, such that the support 200 is the body 100. It is based on being mounted rotatably with respect to.

Body portion 100 is inserted through the insertion hole 104 in the center. Since the body portion 100 may be rotatable from the support 200, the outer shape may be formed to be deformable into various shapes as well as the pipe shape shown in the drawings.

The support 200 has a cylindrical shape, and a probe 201 made of differential coils is inserted in the center of the front surface thereof to protrude forward.

At this time, the rear side of the support 200 is formed such that the size of the outer diameter is smaller than the front side so that the rear end of the support 200 is inserted into the insertion hole 104 of the body portion 100.

In addition, the outer surface of the body portion 100 is formed with a guide hole 101 of a predetermined length to guide the direction of rotation of the support 200, the outer peripheral surface of the support 200 is inserted into the body portion 100 1 insertion groove 202 is formed, the body through the fastening member (B) by having a fastening member (B) that is fastened to the first insertion groove (202) through the guide hole (101) 100 and the support 200 are connected.

At this time, it is preferable that a thread is formed on the inner circumferential surface of the first insertion groove 202 so that the fastening can be performed when the fastening member B is inserted.

The probe tip 300 is detachably provided at the front of the support 200, so that the through hole 301 is formed at the center thereof, so that the probe 201 of the support 200 is inserted into the through hole 301. An end of the probe 201 may protrude forward of the support 200.

In addition, an insertion protrusion 204 is formed on a front surface of the support 200 on which the probe 201 is formed, and an insertion groove (not shown) is formed on a corresponding surface of the probe tip 300 corresponding to the front surface of the support 200. This is formed so that the insertion protrusion 204 is inserted into the insertion groove (not shown) when the support 200 and the probe tip 300 is coupled.

At this time, as another example of the support 200 and the probe tip 300, the insertion groove 204 is formed on the front surface of the support 200 is formed instead of the insertion protrusion 204, the insertion groove (not shown) The corresponding surface of the formed probe tip 300 allows insertion protrusions to be formed instead of insertion grooves so as to couple the support 200 and the probe tip 300 to each other.

On the other hand, the probe tip 300 is preferably formed in various shapes to be provided with a plurality so that it is possible to replace the probe tip 300 according to the situation.

The probe tip 300 has a shape in which the front center protrudes forward (see FIG. 5) as shown in FIG. 6, a shape in which the front center is concavely inserted inward, and the front center is convex outward. The shape (b), the front surface is formed in a plane (c), the refraction shape (d) formed with a step on the front surface, the curved shape (e) in the front, the front end is cut (f) made sharp by cutting both ends To be molded into various shapes.

In addition, a second insertion groove 102 is formed on the outer circumferential surface of the body part 100 so that a bar-shaped handle 110 additionally provided is mounted vertically to the second insertion groove 102. To be shaped.

At this time, the lower portion of the handle 110 to be provided with a connector 111 to be interlocked with the eddy current inspection device (not shown), the connector 111 is to be connected to the probe 201 of the support 200. desirable. Here, the connector 111 and the probe 201 allow the coil c forming the probe 201 to extend to be connected to the connector 111.

The fixing cap 210 is formed in a pipe shape in which the rear end surface is closed, and is fixedly inserted into the end of the support 200 into which the body part 100 is inserted.

At this time, the rear end length of the support body 200 inserted into the body part 100 is formed to be longer than the body part 100 so that the rear end part of the support body 200 protrudes out of the body part 100 so that the fixed cap ( 210 may be inserted into the support 200.

Here, the fixing cap 210 is formed with a third insertion groove 211 to be inserted into the rear end of the support 200, the inner circumferential surface of the third insertion groove 211 and after the support 200 A thread is formed on the outer circumferential surface of the end so that the fixing cap 210 is coupled to the support 200 while rotating, so that the fixing cap 210 is fixed to the support 200 but rotatable about the body portion 100. .

Hereinafter, functions and effects of the present invention will be described.

5 and 7, the support 200 including the probe 201 is rotatably mounted to the pipe-shaped body 100 as shown in FIGS. 5 and 7, and the end of the probe 201 is supported by the support 200. Penetration through the probe tip 300 is located in the front to enable the eddy current inspection of the surface of the subject through the probe 201.

Here, the probe 201 of the present invention is made of differential coils, but the comparative coil is generally applied to the comparative coil because it has better signal sensitivity than an absolute coil in inspection of a flat portion. .

At this time, the support 200 is rotated from the body portion 100 is possible because the rear end of the support 200 is inserted into the insertion hole 104 of the body portion 100, of the body portion 100 The angle of rotation of the support 200 may be adjusted through the bolt B inserted into the guide hole 101 and the first insertion groove 202 of the support 200.

Here, in the case of adjusting the rotation angle of the support 200, after separating the bolt (B) from the guide hole 101 and the first insertion groove 202, the support 200 to fit the work purpose body portion 100 After the rotation is completed, the bolt (B) is fastened to the guide hole 101 and the first insertion groove 202 to fix the support 200 and the body part 100. On the other hand, the rotation angle of the support 200 is made only within the range not exceeding the length of the guide hole 101 formed in the body portion 100.

In addition, a scale 203 is formed on the outer circumferential surface of the support 200, and an arrow-shaped pointer 103 is formed on the outer circumferential surface of the body 100 to rotate the support 200 from the body 100. When the pointer 103 is to determine the rotation angle of the support 200 according to the position of the scale (203).

At this time, the fixing portion 210 is inserted into the end of the support 200 into which the body portion 100 is inserted so that the body portion 100 is positioned between the support 200 and the fixing cap 210. It is preferable to prevent the 100 from being separated from the support 200.

On the other hand, the probe tip 300 is located in front of the support 200, the probe 201 of the support 200 is projected toward the probe tip 300 through the through hole 301 formed in the center, the user When the support 200 rotates in the circumferential direction according to the intention, the probe tip 300 rotates together with the support 200.

Here, the probe tip 300 is detachably provided on the support 200, and can be applied by replacing the probe tip 300 having a shape corresponding to the surface of the object to be inspected as shown in FIG. The plurality of probe tips 300 formed in various shapes so as to be provided.

As such, when the surface of the subject is inserted inwardly, a probe tip (300, see FIGS. 5 and 8) protruding from the front surface is applied, and when the surface of the subject is convex, the front tip is concave. (a) is applied, and if the surface of the subject is concave, the front of the convex shape is applied to the probe tip (b), and if the surface of the object is flat, the front of the probe tip (c) When the surface of the subject is refracted, the front surface is refracted to apply a probe tip having a step (d, see FIG. 9), and when the surface of the subject is curved, the front surface is curved with a probe tip If (e) is applied and the surface of the subject is sharp, both ends of the front surface are cut to apply a probe tip f having a sharp shape to diversify the shape of the probe tip 300, thereby making it impossible to It enables a check on the subject surface of the significant features.

On the other hand, the handle portion 110 is additionally mounted to the body portion 100 to improve the convenience of the operator when inspecting the subject surface.

At this time, the connector 111 provided in the lower portion of the handle 110 is interlocked with the eddy current inspection device (not shown) through a cable, so that the eddy current signal detected from the probe 201 during the surface inspection of the subject through the probe 201. Is transmitted to the eddy current inspection device via the connector 111 connected by the coil (c), it is possible to determine the work state and the work error through the control unit and display means provided in the eddy current inspection device.

Here, when the support 200 is rotated in the circumferential direction according to the shape of the surface of the test object, the probe tip 300 rotates together with the support 200 so that the front of the probe tip 300 is The probe tip 300 may be rotated on the surface of the subject by allowing the body portion 100 to rotate through the handle 110 instead of the rotation of the support 200 according to the shape of the subject surface. By allowing the handle 110 to rotate in a corresponding state, it is possible to improve work convenience.

As described above, the present invention replaces the probe tip 300 in accordance with the shape of the subject, thereby placing the eddy current probe 201 on the surface of the subject and allowing the handle 110 to be varied from side to side. At the same time, the stress concentration site can be inspected by varying the probe 201 in a direction perpendicular to the defect direction, thereby improving the eddy current signal detection sensitivity.

Eddy current probe of the present invention configured as described above and the body; It accommodates a probe made of differential coils and includes a support rotatably mounted to the body portion so that the eddy current inspection direction can be aligned according to the defect direction, and can be positioned perpendicular to the defect surface of the geometric shape. This is an invention having an excellent advantage in improving the test ability and the reliability of the test.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. It is to be understood that various changes and modifications may be made without departing from the scope of the appended claims.

100: body 101: guide hole
102: second insertion groove 110: handle
200 support 201 probe
202: first insertion groove 210: fixed cap
300: probe tip 301: through hole

Claims (7)

A body portion having a cylindrical inner space formed therein;
And a support formed of comparative coils protruding forward, the support being rotatably mounted to the body portion.
The method of claim 1,
A detachable probe tip is provided at the front of the support, and an eddy current probe, characterized in that a through hole is formed at the center of the probe tip to protrude outward from the probe.
The method of claim 1,
A guide hole for guiding the rotation direction of the support is formed in the outer surface of the body portion, and a first insertion groove is formed in the outer circumferential surface of the support, and fastened to the first insertion groove through the guide hole outside the body portion. Eddy current probe comprising a fastening member to be.
The method of claim 2,
The front surface of the probe tip is an eddy current probe, characterized in that the shape corresponding to the surface to be inspected.
The method of claim 1,
The second insertion groove is formed on the outer surface of the body portion, the eddy current probe, characterized in that the handle is mounted in the vertical direction in the second insertion groove.
6. The method of claim 5,
The lower portion of the handle is provided with a connector is interlocked with the eddy current test device, the connector is connected to the probe of the support, characterized in that the eddy current probe.
The method of claim 1,
The body portion penetrates through the support, and an eddy current probe, characterized in that the body is assembled between the support and the fixed cap is inserted into the end of the support cap.

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