JP2013137318A - Eddy current flaw detection probe and eddy current flaw detection testing device using the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an eddy current flaw detection probe capable of preventing a radiation magnetic field from interfering with a detection magnetic field by radiating a magnetic field only from a magnetic field radiation surface of an exciting coil.SOLUTION: An eddy current flaw detection probe 3 comprises: an exciting coil 4 that is disposed with one end surface opposite to a flaw detection surface 100, radiates a magnetic field to the flaw detection surface 100 and generates an eddy current on the flaw detection surface 100 and inside the flaw detection surface 100; a detection coil 8 that is disposed with one end surface opposite to the flaw detection surface 100 and detects a magnetic field generated by variations in the eddy current; and an exciting coil ferrite core 5 that has an axial core portion 5a provided as an axial core of the exciting coil 4 and a protrusion portion protruding from the end surface of the exciting coil 4 opposite to the flaw detection surface 100. A magnetic field shield member 7 is provided on surfaces excluding a magnetic field radiation surface of the protrusion portion of the exciting coil ferrite core 5 via a magnetic field insulation member 6. The exciting coil ferrite core 5 and the magnetic field shield member 7 are formed of a ferromagnetic material such as iron or ferrite.

Description

  The present invention relates to an eddy current flaw detection probe and an eddy current flaw detection test apparatus using the same.

There is an eddy current flaw detection apparatus as a device for detecting flaws and cracks on the inner surface of a conductive member such as a metal tube. The eddy current testing apparatus generates a magnetic field in an excitation coil and irradiates the testing surface of the conductive member by inducing eddy currents on the surface and inside of the conductive member, thereby generating eddy currents caused by scratches and cracks on the conductive member. A flaw or a crack is detected by detecting a magnetic field generated by a change in current flow by entering a detection coil.

In the eddy current testing apparatus, the end face of the detection coil is placed facing the testing surface, so that the magnetic field generated from the change in the eddy current generated on the testing surface is coiled into the ferrite core that is inserted into the detection coil as the axis. Eddy current flaw detectors have been developed that are axially advanced to increase magnetic field detection sensitivity.

In the eddy current flaw detection test apparatus in which the end face of the detection coil is arranged to face the flaw detection surface, the detection sensitivity of the magnetic field increases as the number of turns of the detection coil increases, but the diameter of the coil increases as the number of turns of the coil increases. As a result, the distance between the flaw detection surface and the ferrite core, which is referred to as lift-off, is increased during a flaw detection test on a concave flaw detection surface such as the inside of a metal tube, which in turn causes a decrease in detection accuracy.

In view of this, a technique has been developed in which the ferrite core is provided with a projecting portion along the shape of the inside of the metal tube so that the lift-off becomes an appropriate value for the flaw detection test (see, for example, Patent Document 1).
).

JP 9-49825 A

However, in the above-described technique, since the protrusion of the ferrite core is fitted with a lift-off on the concave inspection surface during the flaw detection test, the magnetic field generated on the inspection surface around the protrusion of the ferrite core is Enter the protruding part. As a result, the spatial resolution of the eddy current flaw test is reduced, such as when it is more difficult to specify the details of the position and size of flaws and cracks than when performing a flaw detection test on a flat surface without a protrusion on the ferrite core. I was invited.

Accordingly, the present invention provides an appropriate value for the lift-off, which is the distance between the ferrite core inserted into the detection coil and the concave flaw detection surface, in an eddy current flaw detection test apparatus in which the end surface of the detection coil is arranged facing the flaw detection surface. In addition, an object of the present invention is to provide an eddy current flaw detection probe and an eddy current flaw detection test apparatus using the eddy current flaw detection probe which can enhance the spatial resolution of the eddy current flaw detection test.

In order to achieve the above object, an eddy current flaw detection probe according to the present invention is arranged with one end face facing a flaw detection surface, and irradiates a magnetic field on the flaw detection surface to generate eddy currents on the flaw detection surface and inside. An excitation coil, a detection coil that is disposed with one end face opposed to the flaw detection surface, detects a magnetic field generated by a change in the eddy current, an axial center provided as an axis of the excitation coil, and the excitation An exciting coil ferrite core having a protruding portion protruding from an end surface facing the flaw detection surface of the coil, and a magnetic field insulating member is provided on a surface of the exciting coil ferrite core excluding the magnetic field irradiation surface. A magnetic field shielding member is provided, and the ferrite core for exciting coil and the magnetic field shielding member are made of a ferromagnetic material such as iron or ferrite.

In order to achieve the above object, an eddy current test apparatus according to the present invention is electrically connected to the above-described eddy current test probe and the excitation coil of the eddy current test probe, and supplies an excitation current to the excitation coil. And a detection device that is electrically connected to the detection coil of the eddy current flaw detection probe and analyzes a change in the magnetic field detected by the detection coil.

According to the present invention, in the eddy current testing apparatus in which the end surface of the detection coil is arranged to face the flaw detection surface, the lift-off that is the distance between the ferrite core inserted into the detection coil and the concave flaw detection surface is an appropriate value. In addition, the spatial resolution of the eddy current flaw detection test can be increased.

1 is a longitudinal sectional view of a metal tube when an eddy current flaw detection apparatus according to an embodiment of the present invention is disposed in the metal tube. FIG. 2 shows a ferrite core for an excitation coil and a ferrite core for a detection coil of an eddy current flaw detection probe according to an embodiment of the present invention, wherein (a) is a perspective view and (b) is a perspective view when the coil is inserted into the coil. The AA sectional view in Drawing 1 showing the magnetic field irradiation part of the eddy current inspection probe concerning the embodiment of the present invention. The BB sectional view in Drawing 1 showing the magnetic field detection part of the eddy current inspection probe concerning the embodiment of the present invention. The figure which shows the example of the protrusion part of the magnetic field irradiation part of the eddy current test probe which concerns on embodiment of this invention.

  Embodiments of the present invention will be described below.

(Constitution)
Hereinafter, an eddy current flaw detection probe and an eddy current flaw detection test apparatus according to an embodiment of the present invention will be described with reference to FIGS. FIG. 1 is a longitudinal sectional view of a metal tube when an eddy current flaw detection test apparatus according to an embodiment of the present invention is disposed in the metal tube.

The eddy current flaw detection probe is configured by providing a flaw detection probe housing 3 with a magnetic field irradiation unit 1 and a magnetic field detection unit 2.

The magnetic field irradiation unit 1 includes an exciting coil 4, an exciting coil ferrite core 5, and a magnetic field insulating member 6.
And the magnetic field shielding member 7. The magnetic field detection unit 2 includes a detection coil 8, a detection coil ferrite core 9, a magnetic field insulating member 10, and a magnetic field shielding member 11.

The magnetic field shielding member 7 has an excitation coil on the surface excluding the magnetic field irradiation surface 21 of the excitation coil ferrite core 5 out of the periphery of the excitation coil ferrite core 5 inserted into the excitation coil 4 as the axis of the excitation coil 4. 4 and the exciting coil ferrite core 5 are provided via a magnetic field insulating member 6.

The magnetic field shielding member 11 has a magnetic field entry surface 22 of the detection coil ferrite core 9 out of the periphery of the detection coil ferrite core 9 inserted into the detection coil 8 as the axis of the detection coil 8.
Is provided via a magnetic field insulating member 10 so as to be separated from the detection coil 8 and the detection coil ferrite core 9 on the surface other than the magnetic field.

Here, the excitation coil 4 and the detection coil 8 are coils formed by winding a conductive metal wire such as copper, and both have a cylindrical shape with a diameter of 30 mm. The exciting coil ferrite core 5, the detecting coil ferrite core 9, and the magnetic shielding members 7 and 11 are made of a ferromagnetic material such as iron or ferrite, and the magnetic insulating members 6 and 10 are plastic, Teflon (registered trademark). ), Non-magnetic material such as glass. The inner diameter of the metal tube 100 is 100 mm.
It is.

The eddy current test apparatus includes an eddy current test probe, a power source 31 and a detection device 32. The power supply 31 is electrically connected to the excitation coil 4, and the detection device 32 is electrically connected to the detection coil 8.

The power source 31 is a device that supplies an exciting current for exciting an eddy current such as an alternating current or a pulse current to the exciting coil 4, and the detecting device 32 is a change in induced current generated by a magnetic field that has entered the detecting coil 4. Therefore, it is a device that measures the magnetic field strength distribution and determines the presence or absence of scratches or cracks.

2A and 2B show a ferrite core for an excitation coil and a ferrite core for a detection coil of an eddy current flaw detection probe according to an embodiment of the present invention, where FIG. 2A is a perspective view and FIG. 2B is a diagram when the ferrite core is inserted into the coil. FIG.

The exciting coil ferrite core 5 includes an axial center portion 5a and a protruding portion 5b. Axial part 5
a has a cylindrical shape that can be inserted into the exciting coil 4 as an axis. The protruding portion 5b has a truncated cone shape with a height of 4 mm, and the lower bottom surface and one cylindrical end surface of the shaft center portion 5a are bonded together. Here, the magnetic field irradiation surface 21 is the upper bottom surface of the truncated cone shape of the protruding portion 5b.

The ferrite core 9 for the detection coil has an axial center portion 9 having the same shape as the ferrite core 5 for the excitation coil.
The magnetic field entrance surface 22 is an upper bottom surface of the truncated cone shape of the projecting portion 9b.

(Function)
Hereinafter, the operation of the embodiment of the present invention will be described. 3 is a cross-sectional view taken along line AA in FIG. 1 showing a magnetic field irradiation unit of the eddy current flaw detection probe according to the embodiment of the present invention. FIG. 4 is a magnetic field detection of the eddy current flaw detection probe according to the embodiment of the present invention. It is BB sectional drawing in FIG. 1 which shows a part.

In the flaw detection test, the magnetic field irradiation surface 21 and the magnetic field entrance surface 22 are opposed to the inner surface of the metal tube 100, and the eddy current flaw detection probe is metalized at a position where the distance between the detection coil 4 and the excitation coil 8 and the metal tube 100 is 1 mm. Arranged inside the tube 100.

At this time, since the diameters of the excitation coil 4 and the detection coil 8 are 30 mm, the distance between the end surfaces of the excitation coil 4 and the detection coil 8 and the inner surface of the metal tube 100 is about 5 mm. The protrusions 5b and 9b of the ferrite core 9 for the detection coil have a truncated cone shape with a height of 4 mm, and the magnetic field irradiation surface 21, the magnetic field entrance surface 22, and the metal tube 100
Lift-off 41, 42, which is the distance from the inner flaw detection surface, is about 1 mm, which is an appropriate value for eddy current flaw detection.
And

When an excitation current for exciting an eddy current is applied to the excitation coil 4 by the power source 31, an irradiation magnetic field 51 is generated outwardly from the excitation coil 4 and the excitation coil ferrite core 5.

Of the irradiation magnetic field 51, the magnetic field shielding member 7 that moves outward through the surface on which the magnetic field shielding member 7 is provided flows into the magnetic field shielding member 7, and the magnetic permeability of the magnetic field shielding member 7 is around the magnetic field shielding member 7. Since it is higher than air, the irradiation magnetic field 51 stays in the magnetic shielding member 7 and does not leak outward from the magnetic shielding member 7. Therefore, the irradiation magnetic field 51 generated by the excitation coil 4 is irradiated on the inner surface of the metal tube 100 only from the magnetic field irradiation surface 21.

When an eddy current is excited on the inner surface and inside of the metal tube 100 by the irradiation magnetic field 51 irradiated from the magnetic field irradiation surface 21 and the metal tube 100 has scratches or cracks, the eddy current changes and a detection magnetic field 52 is generated. .

Of the detection magnetic field 52, one that attempts to enter the detection coil 8 and the detection coil ferrite core 9 through the surface on which the magnetic field shielding member 11 is provided flows into the magnetic field shielding member 11, and Since the magnetic permeability is higher than that of the magnetic field insulating member 10, the detection magnetic field 52 remains in the magnetic field shielding member 11 and does not enter the detection coil 8 and the ferrite core 9 for detection coil. Therefore, the detection magnetic field 52 enters the detection coil ferrite core 9 only from the magnetic field entry surface 22. That is, only the detection magnetic field 52 generated on the surface facing the magnetic field entry surface 22 and the vicinity thereof on the inner surface of the metal tube 100 enters the detection coil ferrite core 9.

An induced current is generated in the detection coil 8 by the detection magnetic field 52 that has entered the ferrite core 9 for the detection coil. The detection device 32 detects the induced current generated in the detection coil 8, measures the magnetic field strength distribution, and determines the presence or absence of scratches or cracks by comparing with the reference value.

In addition, the magnetic field irradiation part 21 arrange | positions the exciting coil 4 whose diameter is 98 mm so that a coil axial direction may become parallel to the longitudinal direction of a metal tube, and the shape of the ferrite core 5 for exciting coils is the protrusion part 5.
A configuration in which b is omitted may be employed. At this time, since the diameter of the exciting coil 4 is 98 mm with respect to the diameter 100 mm of the metal tube 100, the lift-off between the metal tube 100 and the exciting coil 4 is 1 mm, which is an appropriate value.

(effect)
According to this embodiment, the metal tube 1 is formed by the protruding portion 9b of the ferrite core 9 for the detection coil.
The lift-off 42 that is the distance between the inner surface of 00 and the magnetic field entrance surface 22 can be set to an appropriate value for the flaw detection test.

In addition, since the eddy current flaw detection test can be performed only with the detection magnetic field 52 generated on the inner surface of the metal tube 100 facing the magnetic field entrance surface 22 and in the vicinity thereof, compared with the case where the magnetic field shielding member 11 is not provided. Spatial resolution can be increased.

Furthermore, since the irradiation magnetic field 51 is irradiated on the inner surface of the metal tube 100 only from the magnetic field irradiation surface 21, it is possible to prevent the irradiation magnetic field 51 from directly entering the detection coil 8 and interfering with the detection magnetic field 52.

Needless to say, the embodiment of the present invention is not limited to the above-described embodiment. For example, the diameters of the detection coil 4 and the excitation coil 8 can be appropriately changed according to the diameter of the metal tube 100 and the required detection sensitivity, and the exciting coil ferrite core 5 and the protruding portion 5b of the detection coil ferrite core 9 The height of the truncated cone shape of 9b is also changed as appropriate to a height at which lift-offs 41 and 42 suitable for the flaw detection test can be taken according to the shape of the metal tube 100.

FIG. 5 is a diagram illustrating an example of the protrusion of the magnetic field irradiation unit of the eddy current flaw detection probe according to the embodiment of the present invention. The concave-shaped flaw detection surface that can be flaw-detected by the magnetic field irradiation unit 1 of the present embodiment is not limited to the above-described cylindrical inner shape, but a staircase shape in which one side is depressed, the inside of a square groove, a continuous uneven shape, etc. Can be detected. At this time, the protruding portion 5b of the exciting ferrite core 5 of the magnetic field irradiation unit 1
Is a shape that can be fitted into each concave-shaped flaw detection surface with a lift-off appropriate for the flaw detection test. Similarly, the magnetic field detection unit 2 has a protruding portion 9 of the ferrite core 9 for detection.
By making b a shape that can be fitted with a lift-off appropriate for the flaw detection test on the concave flaw detection surface, flaw detection with various concave shapes becomes possible.

Further, the positions and areas of the magnetic field irradiation surface 21 and the magnetic field entrance surface 22 can be appropriately changed by changing the positions and areas where the magnetic field insulating members 6 and 10 and the magnetic field shielding members 7 and 11 are provided according to the flaw detection range to be obtained. However, a curved shape along the inner surface of the metal tube 100 may be used.

Moreover, if the magnetic field shielding member 7 is provided on at least the surface of the projecting portion 5b of the exciting coil ferrite core 5 excluding the magnetic field irradiation surface 21, that is, on the frustoconical side peripheral surface, the spatial resolution is increased. be able to. Similarly, if the magnetic field shielding member 11 is provided on at least the surface of the protruding portion 9b of the detection coil ferrite core 9 excluding the magnetic field entrance surface 22, that is, the frustoconical side peripheral surface, the spatial resolution is reduced. Can be increased.

Further, the magnetic field insulating member 6 does not have to be provided on the entire surface below the magnetic field shielding member 7 as long as the magnetic field shielding member 7 is provided apart from the exciting coil 4 and the ferrite core 5 for exciting coil. Similarly, as long as the magnetic field shielding member 11 is provided apart from the detection coil 8 and the detection coil ferrite core 9, the magnetic field insulating member 10 may not be provided below the entire surface where the magnetic field shielding member 11 is provided.

In addition, the magnetic field irradiation unit 1 and the magnetic field detection unit 2 are provided with an excitation coil 4 and a detection coil 8 wound in advance, and an axial center portion 5a of the excitation coil ferrite core 5 and the detection coil ferrite core 9, respectively.
, 9a may be inserted and configured, and the exciting coil 4 and the detection coil 8 may be formed by winding a conductive metal wire around the shaft center portions 5a, 9a.

DESCRIPTION OF SYMBOLS 1 ... Magnetic field irradiation part 2 ... Magnetic field detection part 3 ... Eddy current test probe housing | casing 4 ... Excitation coil 5 ... Ferrite core 5a for excitation coils ... Axial part 5b ... Projection 6 ... Magnetic field insulating member 7 ... Magnetic field shielding member 8 ... Detection coil 9 ... Detection coil ferrite core 9a ... Shaft core 9b ... Projection 10 ... Magnetic field insulation Member 11 ... Magnetic field shielding member 21 ... Magnetic field irradiation surface 22 ... Magnetic field entry surface 31 ... Power source 32 ... Detection device 41 ... Lift-off 42 ... Lift-off 51 ... Irradiation magnetic field 52 ... Detection magnetic field 100 ... Metal tube

Claims (2)

An excitation coil that is arranged with one end face facing the flaw detection surface, irradiates the flaw detection surface with a magnetic field, and generates eddy currents in the flaw detection surface and inside;
A detection coil that is disposed with one end face facing the flaw detection surface and detects a magnetic field generated by the change in the eddy current;
An excitation coil ferrite core having an axial center provided as an axis of the excitation coil and a protruding portion protruding from an end surface of the excitation coil facing the flaw detection surface;
Of the protrusions of the exciting coil ferrite core, a magnetic field shielding member is provided on a surface excluding the magnetic field irradiation surface via a magnetic field insulating member,
The eddy current flaw detection probe according to claim 1, wherein the exciting coil ferrite core and the magnetic field shielding member are made of a ferromagnetic material such as iron or ferrite. An eddy current flaw detection probe according to claim 1;
A power source electrically connected to the excitation coil of the eddy current flaw detection probe and supplying an excitation current to the excitation coil;
A detection device that is electrically connected to the detection coil of the eddy current testing probe and analyzes the change in the magnetic field detected by the detection coil;
An eddy current flaw testing apparatus characterized by comprising:

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