JP5008697B2 - Nondestructive inspection equipment - Google Patents

Description

  The present invention relates to a nondestructive inspection apparatus.

  As a non-destructive inspection technology that detects discontinuities such as flaws and defects without physically destroying the inspection object, one that measures the magnetic field (magnetic field) from the surface of the inspection object using a magnetic sensor is known. Yes. For example, high-sensitivity FG (Flux-Gate) sensor, MI (Magneto-Impedance) sensor, and high-sensitivity SQUID (Superconducting QUantum Interference Device) as magnetic sensors It is possible to detect the discontinuous portion by measuring the leakage magnetic flux caused by the discontinuous portion inside or on the surface of the inspection object.

  In addition, an eddy current test (eddy current test) in which an eddy current is induced in a test object by a magnetic field generated from a coil and a discontinuous portion of the test object is detected by measuring the magnetic field generated by the eddy current; A so-called nondestructive inspection method (hereinafter referred to as eddy current method) is also generally known. For example, in Patent Document 1, the amplitude of each frequency component of a magnetic field measured by the eddy current method is calculated, and the difference between the amplitudes of different frequency components is calculated, whereby the distance between the magnetic sensor and the inspection object is calculated. A nondestructive inspection apparatus that can reduce the influence of changes is disclosed.

  By the way, the non-destructive inspection apparatus as described above is of a scanning type that moves the inspection object side substantially parallel to the sensor surface of the fixed magnetic sensor, and the non-destructive inspection apparatus is substantially relative to the surface of the fixed inspection object. It can be roughly classified into a scanning type that moves the magnetic sensor side in parallel. For example, when the inspection object is a large structure such as a power facility, a scanning method on the magnetic sensor side is generally employed. For example, Patent Document 2 discloses a nondestructive inspection apparatus and method that keeps the distance and angle between a magnetic sensor and an inspection object constant by scanning the magnetic sensor using a multi-axis robot.

  Thus, the discontinuous part of the inspection object can be detected by scanning the inspection object side or the magnetic sensor side and measuring the magnetic field from the surface of the inspection object.

JP 2003-149212 A JP 2006-329632 A

Here, FIG. 13 shows an example of the configuration of a general nondestructive inspection apparatus using the eddy current method.
In the nondestructive inspection apparatus shown in FIG. 13, the sensor unit 1 includes, for example, a SQUID and the like, and a detection coil 11 is connected to constitute a magnetic sensor. The alternating current supply unit 4 is connected to an exciting coil 41 that generates an alternating magnetic field to form a magnetic field generating unit. The nondestructive inspection apparatus scans the inspection object 9 side or the detection coil 11 and the excitation coil 41 side. In any case, the smaller the area of the detection coil 11, the better the spatial resolution of the inspection. Can be made.

  However, if the area of the detection coil 11 is reduced, the inspection time of the entire inspection object 9 is increased. Further, in order to achieve both spatial resolution and inspection time, when a plurality of detection coils are arranged adjacent to each other, the same number of sensor units as the detection coils are required. For example, as shown in FIG. 14, when the detection coils 11a to 11i are arranged corresponding to the 3 × 3 areas A to I, nine sensor units 1a to 1i are required.

  For this reason, the same number of SQUIDs and the like provided in each sensor unit are required as the number of detection coils, which increases the cost of the nondestructive inspection apparatus. In addition, as the number of sensor units increases, it becomes more difficult to align characteristics such as SQUID, and further, wiring for connecting the sensor unit and the detection coil becomes more difficult.

The main present invention that solves the above-described problem includes a plurality of exciting coils that are partially overlapped to form a plurality of regions having substantially the same shape, and that have a smaller number than the plurality of regions . One of the exciting coils is sequentially selected, and a magnetic field generator that generates an alternating magnetic field that induces eddy currents in the inspection object, and measurement magnetic field data corresponding to the magnetic field generated by the eddy currents are output. A nondestructive inspection apparatus comprising: a magnetic sensor; and a data processing unit that obtains a magnetic field generated by the eddy current for each of the plurality of regions based on the measured magnetic field data.

  Other features of the present invention will become apparent from the accompanying drawings and the description of this specification.

  According to the present invention, the spatial resolution can be improved without increasing the number of magnetic sensors.

It is a top view which shows the detail of a structure of the nondestructive inspection apparatus in 1st Embodiment of this invention. It is a perspective view which shows the outline of a structure of the nondestructive inspection apparatus in the 1st thru | or 3rd embodiment of this invention. It is a top view which shows the detail of a structure of the nondestructive inspection apparatus in 2nd Embodiment of this invention. It is a figure explaining the calculation method of distribution for every field of a magnetic field generated by eddy current in a 2nd embodiment of the present invention. It is a top view which shows the detail of a structure of the nondestructive inspection apparatus in 3rd Embodiment of this invention. It is a figure explaining the calculation method of distribution for every field of the magnetic field generated by eddy current in a 3rd embodiment of the present invention. It is a figure which shows the example of arrangement | positioning which arranges a triangular coil adjacently. It is a figure which shows the other example of arrangement | positioning which arranges a triangular coil adjacently. It is a figure which shows the example of arrangement | positioning which arranges a regular hexagonal coil adjacently. It is a figure which shows the other example of arrangement | positioning which arrange | positions a part of rectangular coil. It is a figure which shows the further other example of arrangement | positioning which arrange | positions a part of rectangular coil. It is a figure which shows the example of arrangement | positioning which arrange | positions and arrange | positions a part of regular hexagonal coil. It is a perspective view which shows an example of a structure of a general nondestructive inspection apparatus. It is a top view which shows an example of a structure of the nondestructive inspection apparatus which has arrange | positioned the several detection coil adjacently.

  At least the following matters will become apparent from the description of this specification and the accompanying drawings.

<First Embodiment>
=== Configuration of Nondestructive Inspection Apparatus ===
The configuration of the nondestructive inspection apparatus according to the first embodiment of the present invention will be described below with reference to FIGS. 2 is a perspective view schematically showing the configuration of the nondestructive inspection apparatus, and FIG. 1 is a plan view showing details of the configuration of the alternating current supply unit 3 and the exciting coil group 31 in the nondestructive inspection apparatus. FIG.

  The nondestructive inspection apparatus shown in FIG. 2 is an apparatus for detecting a discontinuous portion 91 inside or on the surface of an inspection object 9 using an eddy current method. The non-destructive inspection device includes a sensor unit 1, a detection coil 11, and data. The processing unit 2, the alternating current supply unit 3, and the exciting coil group 31 are configured. The sensor unit 1 is connected to a detection coil 11 to form a magnetic sensor, and the alternating current supply unit 3 is connected to an excitation coil group 31 to form a magnetic field generation unit. Further, as shown in FIG. 1, the alternating current supply unit 3 includes an alternating current generation unit 32, a DEMUX (demultiplexer) 33, and a counter 34. The excitation coil group 31 includes excitation coils 31a to 31i. Is included.

  The output signal of the AC generator 32 is input to the data input of the DEMUX 33, and the count value CN output from the counter 34 is input to the selection control input of the DEMUX 33. In addition, excitation coils 31a to 31i, which are substantially the same rectangular (square or rectangular) coils, are connected to the nine outputs corresponding to the value of the selection control input of the DEMUX 33, respectively. As shown in FIG. 1, the exciting coils 31a to 31i are arranged in a plane adjacent to a matrix of 3 rows and 3 columns, and form substantially the same rectangular areas A to I, respectively. .

  A detection coil 11 is connected to the sensor unit 1, and measured magnetic field data Hq output from the sensor unit 1 is input to the data processing unit 2. Further, the count value CN is also input to the data processing unit 2.

=== Operation of Non-Destructive Inspection Apparatus ===
Next, the operation of the nondestructive inspection apparatus in this embodiment will be described. In the present embodiment, it is assumed that the sensor unit 1 has sufficient sensitivity to measure the magnetic field H2 generated by the eddy current. In the present embodiment, as an example, a case where the sensor unit 1 includes a SQUID will be described.

  The nondestructive inspection apparatus of this embodiment may scan either the inspection object 9 side or the detection coil 11 side. When scanning the inspection object 9 side, the detection coil 11 is fixed, and the inspection object 9 moves substantially parallel to the coil surface of the detection coil 11. The moving direction of the inspection object 9 in this case is indicated by arrows in the x0 direction and the y0 direction in FIGS. On the other hand, when scanning the detection coil 11 side, the inspection object 9 is fixed, and the detection coil 11 moves substantially parallel to the surface of the inspection object 9. The moving direction of the detection coil 11 in this case is indicated by arrows in the x1 direction and the y1 direction in FIGS. It is assumed that the positional relationship between the detection coil 11 and the excitation coil group 31 does not change even when the detection coil 11 side is scanned.

  The counter 34 of the alternating current supply unit 3 sequentially counts up or down and outputs a count value CN. In the present embodiment, the counter 34 is, for example, a 4-bit binary counter, and the count value CN sequentially increases from 0 to 8 (from 0000 to 1000 in binary number) or decreases sequentially from 8 to 0. Further, the DEMUX 33 sequentially selects any one of the exciting coils 31a to 31i according to the count value CN, and supplies the selected exciting coil with the alternating current generated by the alternating current generating unit 32. Therefore, the alternating current supply unit 3 sequentially flows the alternating currents Ia to Ii through the exciting coils 31a to 31i, respectively, generates alternating magnetic fields in the rectangular areas A to I, respectively, and induces eddy currents in the inspection object 9. .

  The detection coil 11 detects a magnetic field H2 generated by the eddy current. Further, the sensor unit 1 outputs measured magnetic field data Hq according to the strength of the magnetic field or the magnetic flux density at the position of the detection coil 11. Therefore, the measurement magnetic field data Hq is output according to the strength or magnetic flux density of the magnetic field H2 that is sequentially generated in the rectangular areas A to I by the eddy current at the vertical position of the detection coil 11 with respect to the surface of the inspection object 9.

  Based on the measured magnetic field data Hq and the count value CN indicating the excitation coil selected in the DEMUX 33, the data processing unit 2 calculates a distribution for each rectangular area A to I of the magnetic field H2 generated by the eddy current. Here, when the discontinuous portion 91 exists in the inspection target 9, the eddy current is disturbed by the discontinuous portion 91, and the magnetic field H2 generated by the eddy current becomes weak, so the value of the measured magnetic field data Hq decreases. . Therefore, the calculated magnetic field distribution indirectly indicates the distribution of the discontinuous portions 91 in the inspection object 9 or on the surface thereof.

  In addition, when the frequency of the alternating current generated by the alternating current generating unit 32 is increased and the frequency of the alternating magnetic field generated from the exciting coil group 31 is increased, an eddy current is induced only on the substantially surface of the inspection object 9 due to the skin effect, A discontinuous portion 91 on the surface of the inspection object 9 can be detected. On the other hand, when the frequency is lowered, the skin depth increases, so that the discontinuous portion 91 inside the inspection object 9 can be detected. Further, the alternating current and the alternating magnetic field may include a plurality of frequency components.

  In this way, by calculating the distribution for each of the rectangular areas A to I of the magnetic field H2 generated by the eddy current at each measurement location (horizontal position of the detection coil 11 with respect to the surface of the inspection object 9), the inspection object 9 is calculated. The discontinuous part 91 can be detected. Therefore, the magnetic field distribution for each of the nine rectangular areas can be calculated using one sensor unit 1 having a SQUID. Further, by moving the measurement location for each size of the entire exciting coil group 31, the spatial resolution can be improved without increasing the inspection time of the entire inspection object 9. Hereinafter, such an inspection process for moving the entire exciting coil group 31 for each size is referred to as a basic inspection process.

Second Embodiment
=== Configuration of Nondestructive Inspection Apparatus ===
The configuration of the nondestructive inspection apparatus according to the second embodiment of the present invention will be described below with reference to FIG. In addition, the outline of the structure of the nondestructive inspection apparatus in this embodiment is shown by FIG. 2 similarly to 1st Embodiment. FIG. 3 is a plan view showing details of the configuration of the alternating current supply unit 3 and the exciting coil group 31 in the non-destructive inspection apparatus.

  In the nondestructive inspection apparatus of this embodiment, as shown in FIG. 3, the alternating current supply unit 3 includes an alternating current generation unit 32, a DEMUX 33, and a counter 34, and the excitation coil group 31 includes an excitation coil. 31r and 31s are included.

  Similar to the nondestructive inspection apparatus of the first embodiment, the output signal of the AC generator 32 is input to the data input of the DEMUX 33, and the count value CN output from the counter 34 is input to the selection control input of the DEMUX 33. Yes. Excitation coils 31r and 31s are connected to two outputs corresponding to the value of the selection control input of the DEMUX 33, respectively.

  The exciting coils 31r and 31s are substantially the same rectangular coils, and are arranged so as to overlap each other by about one half. Here, as shown in FIG. 3, if the size of each exciting coil is 2a × b, the exciting coils 31r and 31s form rectangular regions J to L having a size of about a × b. Accordingly, two rectangular coils that are substantially the same form three rectangular regions having an area that is approximately one-half of the rectangular coil, and an average (3 ÷ 2 =) 1.5 per exciting coil. Regions are formed.

=== Operation of Non-Destructive Inspection Apparatus ===
Next, the operation of the nondestructive inspection apparatus in this embodiment will be described. Note that, similarly to the first embodiment, the sensor unit 1 also includes a SQUID in this embodiment.

  Similar to the first embodiment, the nondestructive inspection apparatus of the present embodiment may scan either the inspection object 9 side or the detection coil 11 side.

  The counter 34 of the alternating current supply unit 3 sequentially counts up or down and outputs a count value CN. In the present embodiment, the counter 34 is, for example, a 1-bit binary counter, and the count value CN sequentially increases from 0 to 1 or sequentially decreases from 1 to 0. Further, the DEMUX 33 sequentially selects one of the exciting coils 31r or 31s according to the count value CN, and supplies the alternating current generated by the alternating current generating unit 32 to the selected exciting coil.

  Accordingly, the alternating current supply unit 3 sequentially causes the alternating currents Ir and Is to flow through the exciting coils 31 r and 31 s, thereby sequentially generating an alternating magnetic field, and induces an eddy current in the inspection object 9. Note that an alternating magnetic field is generated in the rectangular regions J and K while the alternating current Ir flows through the exciting coil 31r. Further, an alternating magnetic field is generated in the rectangular regions K and L while the alternating current Is flows through the exciting coil 31s.

  Similar to the nondestructive inspection apparatus of the first embodiment, the detection coil 11 detects the magnetic field H2 generated by the eddy current. Further, the sensor unit 1 outputs measured magnetic field data Hq according to the strength of the magnetic field or the magnetic flux density at the position of the detection coil 11. Further, the data processing unit 2 calculates the distribution of the magnetic field H2 generated by the eddy current for each of the rectangular areas J to L based on the measured magnetic field data Hq and the count value CN indicating the excitation coil selected in the DEMUX 33. To do. A detailed description of the calculation method of the magnetic field distribution in this embodiment will be described later.

  In this way, the discontinuous portion 91 of the inspection object 9 can be detected by calculating the distribution of the magnetic field H2 generated by the eddy current for each rectangular area J to L at each measurement location. Therefore, the magnetic field distribution for each of the three rectangular areas can be calculated using one sensor unit 1 having a SQUID.

=== Calculation Method of Magnetic Field Distribution ===
Hereinafter, with reference to FIG. 3 and FIG. 4, the calculation method of the magnetic field distribution in the present embodiment will be described.

  As described above, in the nondestructive inspection apparatus according to the present embodiment, since the sensor unit 1 includes the SQUID, the weak magnetic field H2 generated by the eddy current can be measured. Therefore, the nondestructive inspection apparatus of the present embodiment can detect a small discontinuous portion in the initial stage before the adverse effect on the inspection object 9 becomes obvious, and appropriately implement measures such as replacement and repair. The number of discontinuities detected in one inspection is usually small. Therefore, first, a case will be described in which the number of discontinuous portions in which eddy current is disturbed is 1 or less at one measurement location.

  FIG. 4 shows measured magnetic field data Hq while an alternating current is flowing in each exciting coil when there is no discontinuous portion in any of the rectangular regions J to L, or when there is one discontinuous portion. And the amount of decrease. In FIG. 4, for convenience of explanation, the magnetic field H2 is generated by the eddy current so that the value of the measured magnetic field data Hq is 2 (1 per rectangular area), and there is no eddy in the rectangular area where the discontinuity exists. It is assumed that no current flows. Further, the values (without parentheses) in the upper part of FIG. 4 indicate a decrease in the value of the measured magnetic field data Hq due to the discontinuous portion. In this case, the value of the measured magnetic field data Hq is as shown in FIG. It can be obtained as shown in the lower formula (with parentheses).

  When the discontinuous portion does not exist in any of the rectangular regions J to L (hereinafter referred to as “none” in FIGS. 4 and 6), the decrease in the value of the measured magnetic field data Hq due to the discontinuous portion. The minute is 0, and Hq = 2-0 = 2. When there is one discontinuous portion in the rectangular area J, the value of the measured magnetic field data Hq is decreased by 1 corresponding to one rectangular area only while the alternating current Ir flows through the exciting coil 31r. (Hereinafter referred to as “−1” in FIG. 4 and FIG. 6), and Hq = 2−1 = 1. Further, when there is one discontinuous portion in the rectangular region L, the value of the measured magnetic field data Hq is decreased by 1 only while the alternating current Is flows through the exciting coil 31s, and Hq = 2-1 = 1 When there is one discontinuous portion in the rectangular area K, the value of the measured magnetic field data Hq is decreased by 1, and Hq = 2-1 = 1.

  As is clear from the above, the rectangular area where the discontinuity exists can be identified based on the measured magnetic field data Hq and the count value CN indicating the exciting coil through which the alternating current flows. Further, in the basic inspection process in which the measurement location is moved for each size (approximately 3a × b) of the entire exciting coil group 31, the spatial resolution can be improved without increasing the inspection time of the entire inspection object 9.

  In the nondestructive inspection apparatus according to the present embodiment, the number of exciting coils to be used (2) is smaller than the number of rectangular areas (3), so that it is easy to connect between the alternating current supply unit 3 and the exciting coil group 31. Can be wired.

  Next, a case where the number of discontinuous portions that cause turbulence in eddy current is two or more at one measurement location will be described.

When there are a plurality of discontinuous portions, the amount of decrease in the value of each measured magnetic field data due to the discontinuous portions is obtained by adding the value (0 or −1) in each rectangular area in FIG. 4 by the number of discontinuous portions. That's fine.
For example, when one discontinuous portion is present in each of the rectangular regions J and K, the value of the measured magnetic field data Hq decreases by 2 while the alternating current Ir flows through the exciting coil 31r, and Hq = 2− 2 = 0. Further, while the alternating current Is is flowing through the exciting coil 31s, the value of the measured magnetic field data Hq is decreased by 1, and Hq = 2-1 = 1.

  For example, when one discontinuous portion exists in each of the rectangular regions J and L, the value of the measured magnetic field data Hq is decreased by 1, and Hq = 2-1 = 1. In this case, it cannot be distinguished from the case where one discontinuous portion exists in the rectangular area K, but in FIG. 3, the measurement location is moved by the distance a in the x0 (x1) direction, that is, by one rectangular area. By making it, it becomes possible to distinguish both. If one discontinuous part exists in the rectangular areas J and L before the movement, one discontinuous part exists in the rectangular area K after the movement. On the other hand, when one discontinuous part exists in the rectangular area K before the movement, one discontinuous part exists in the rectangular area J after the movement.

  In this way, it is more desirable to distinguish the case where discontinuous portions exist in a plurality of rectangular areas by moving the measurement location by one rectangular area in the x0 (x1) direction. In addition, it is not necessary to perform such a fine movement with respect to the whole inspection object 9, and it is additional only to the measurement location where the decrease in the value of the measured magnetic field data Hq is not 0 in the basic inspection process. It is enough to go to. Therefore, the inspection time of the entire inspection object 9 is not significantly increased. Hereinafter, such an inspection process of moving by one rectangular area is referred to as an additional inspection process.

<Third Embodiment>
=== Configuration of Nondestructive Inspection Apparatus ===
The configuration of the nondestructive inspection apparatus according to the third embodiment of the present invention will be described below with reference to FIG. In addition, the outline of the structure of the nondestructive inspection apparatus in this embodiment is shown by FIG. 2 similarly to 1st Embodiment. FIG. 5 is a plan view showing details of the configuration of the AC current supply unit 3 and the exciting coil group 31 in the non-destructive inspection apparatus.

  In the nondestructive inspection apparatus of this embodiment, as shown in FIG. 5, the alternating current supply unit 3 includes an alternating current generation unit 32, a DEMUX 33, and a counter 34. 31r to 31u are included.

  Similar to the nondestructive inspection apparatus of the first embodiment, the output signal of the AC generator 32 is input to the data input of the DEMUX 33, and the count value CN output from the counter 34 is input to the selection control input of the DEMUX 33. Yes. In addition, excitation coils 31r to 31u are connected to four outputs corresponding to the value of the selection control input of the DEMUX 33, respectively.

  The exciting coils 31r to 31u are substantially the same rectangular coils. Further, two adjacent exciting coils, that is, the exciting coils 31r and 31s, 31r and 31t, 31s and 31u, and 31t and 31u are arranged so as to overlap each other by approximately one half. Here, as shown in FIG. 5, if each exciting coil is a rectangular (square) coil having a size of 2a × 2a, the exciting coils 31r to 31u are rectangular (square) regions A to I having a size of approximately a × a. Form. Accordingly, nine rectangular regions having an area of approximately one quarter of the rectangular coils are formed by substantially the same four rectangular coils, and an average (9 ÷ 4 =) 2.25 per excitation coil. Regions are formed.

=== Operation of Non-Destructive Inspection Apparatus ===
Next, the operation of the nondestructive inspection apparatus in this embodiment will be described. Note that, similarly to the first embodiment, the sensor unit 1 also includes a SQUID in this embodiment.

  Similar to the first embodiment, the nondestructive inspection apparatus of the present embodiment may scan either the inspection object 9 side or the detection coil 11 side.

  The counter 34 of the alternating current supply unit 3 sequentially counts up or down and outputs a count value CN. In the present embodiment, the counter 34 is, for example, a 2-bit binary counter, and the count value CN is sequentially increased from 0 to 3 (from binary to 00 to 11) or sequentially decreased from 3 to 0. Further, the DEMUX 33 sequentially selects any one of the exciting coils 31r to 31u according to the count value CN, and supplies the selected exciting coil with the alternating current generated by the alternating current generating unit 32.

  Therefore, the alternating current supply unit 3 sequentially flows the alternating currents Ir and Is to the exciting coils 31 r to 31 u to sequentially generate an alternating magnetic field, thereby inducing an eddy current in the inspection object 9. Note that an alternating magnetic field is generated in the rectangular regions A, B, D, and E while the alternating current Ir flows through the exciting coil 31r. Further, an alternating magnetic field is generated in the rectangular regions B, C, E, and F while the alternating current Is flows through the exciting coil 31s. Furthermore, an alternating magnetic field is generated in the rectangular regions D, E, G, and H while the alternating current It flows through the exciting coil 31t. An alternating magnetic field is generated in the rectangular regions E, F, H, and I while the alternating current Iu flows through the exciting coil 31u.

  Similar to the nondestructive inspection apparatus of the first embodiment, the detection coil 11 detects the magnetic field H2 generated by the eddy current. Further, the sensor unit 1 outputs measured magnetic field data Hq according to the strength of the magnetic field or the magnetic flux density at the position of the detection coil 11. Furthermore, the data processing unit 2 calculates the distribution of the magnetic field H2 generated by the eddy current for each rectangular area A to I based on the measured magnetic field data Hq and the count value CN indicating the excitation coil selected in the DEMUX 33. To do. A detailed description of the calculation method of the magnetic field distribution in this embodiment will be described later.

  In this way, the discontinuous portion 91 of the inspection object 9 can be detected by calculating the distribution of the magnetic field H2 generated by the eddy current for each rectangular area A to I at each measurement location. Therefore, the magnetic field distribution for each of the nine rectangular areas can be calculated using one sensor unit 1 having a SQUID.

=== Calculation Method of Magnetic Field Distribution ===
Hereinafter, with reference to FIG. 5 and FIG. 6, the calculation method of the magnetic field distribution in the present embodiment will be described.

  As described above, in the nondestructive inspection apparatus according to the present embodiment, since the sensor unit 1 includes the SQUID, the weak magnetic field H2 generated by the eddy current can be measured. Therefore, the nondestructive inspection apparatus of the present embodiment can detect a small discontinuous portion in the initial stage before the adverse effect on the inspection object 9 becomes obvious, and appropriately implement measures such as replacement and repair. The number of discontinuities detected in one inspection is usually small. Therefore, first, a case will be described in which the number of discontinuous portions in which eddy current is disturbed is 1 or less at one measurement location.

  FIG. 6 shows measured magnetic field data Hq while alternating current is flowing in each exciting coil when there is no discontinuous portion in any of the rectangular regions A to I, or when there is one discontinuous portion. And the amount of decrease. In FIG. 6, for convenience of explanation, a magnetic field H2 is generated by the eddy current so that the value of the measured magnetic field data Hq is 4 (1 per rectangular area), and there is no eddy in the rectangular area where the discontinuity exists. It is assumed that no current flows. Each value in the upper part of FIG. 6 indicates a decrease in the value of the measured magnetic field data Hq due to the discontinuous portion. In this case, the value of the measured magnetic field data Hq is as shown in each lower part of FIG. Can be sought.

  For example, when there is one discontinuous portion in the rectangular area A, the value of the measured magnetic field data Hq is decreased by 1 corresponding to one rectangular area only while the alternating current Ir flows through the exciting coil 31r. Hq = 4-1 = 3. For example, when there is one discontinuous part in the rectangular area E, the value of the measured magnetic field data Hq is decreased by 1, and Hq = 4-1 = 3. Further, for example, when there is one discontinuous portion in the rectangular region F, the measurement magnetic field is only obtained while the alternating current Is flows through the exciting coil 31s and while the alternating current Iu flows through the exciting coil 31u. The value of the data Hq is decreased by 1, and Hq = 4-1 = 3.

  As is apparent from FIG. 6, the rectangular area where the discontinuity exists can be identified based on the measured magnetic field data Hq and the count value CN indicating the exciting coil through which an alternating current flows. Further, in the basic inspection process in which the measurement location is moved for each size (approximately 3a × 3a) of the entire exciting coil group 31, the spatial resolution can be improved without increasing the inspection time of the entire inspection object 9.

  In the nondestructive inspection apparatus according to the present embodiment, the number of exciting coils to be used (4) is smaller than the number of rectangular areas (9), so that the AC current supply unit 3 and the exciting coil group 31 can be easily connected. Can be wired. Further, since the average number of regions formed per excitation coil is larger than that of the nondestructive inspection apparatus of the second embodiment, the spatial resolution can be improved more efficiently.

Next, a case where the number of discontinuous portions that cause turbulence in eddy current is two or more at one measurement location will be described.
In the case where there are a plurality of discontinuous portions, the decrease in the value of each measured magnetic field data due to the discontinuous portions is the value (0 or −1) in each rectangular area in FIG. 6, as in the second embodiment. Should be added by the number of discontinuous portions.

  For example, when one discontinuous portion is present in each of the rectangular regions D and E, the measurement magnetic field is measured while the alternating current Ir is flowing through the exciting coil 31r and while the alternating current It is flowing through the exciting coil 31t. The value of the data Hq is decreased by 2, and Hq = 4-2 = 2. Further, while the alternating current Is is flowing through the exciting coil 31s and while the alternating current Iu is flowing through the exciting coil 31u, the value of the measured magnetic field data Hq is decreased by 1, and Hq = 4-1 = 3 It becomes.

  For example, when one discontinuous part exists in each of the rectangular regions B and H, the value of the measured magnetic field data Hq is decreased by 1, and Hq = 4-1 = 3. In this case, it cannot be distinguished from the case where one discontinuous portion exists in the rectangular area E, but in FIG. 5, the measurement location is moved by the distance a in the y0 (y1) direction, that is, by one rectangular area. By making it, it becomes possible to distinguish both. When one discontinuous part exists in the rectangular areas B and H before the movement by the movement, one discontinuous part exists in the rectangular area E after the movement. On the other hand, when one discontinuous part exists in the rectangular area E before the movement, one discontinuous part exists in the rectangular area B after the movement.

  Furthermore, similarly, the case where one discontinuous portion is present in each of the rectangular regions D and F and the case where one discontinuous portion is present in the rectangular region E are the rectangular regions in the x0 (x1) direction in FIG. By moving only one piece, both can be distinguished.

  In this way, the case where the discontinuous portion exists in a plurality of rectangular areas is also distinguished by the additional inspection process in which the measurement location is moved by one rectangular area in the x0 (x1) direction or the y0 (y1) direction. Is more desirable. Note that it is sufficient that the additional inspection process is additionally performed only on measurement points where the decrease in the value of the measured magnetic field data Hq in the basic inspection process is not 0 for a plurality of exciting coils. Therefore, the inspection time of the entire inspection object 9 is not significantly increased.

=== Other arrangement examples of exciting coils ===
The exciting coil group 31 can have various configurations other than the arrangement examples of the exciting coils shown in FIGS. 1, 3, and 5. If the shape of each exciting coil and the shape of each region are different, the measured magnetic field data Hq also varies at a measurement location where there is no discontinuous portion, and the data processor 2 weights each exciting coil or region. It is necessary to correct such as. Therefore, it is desirable that the shape of each exciting coil and the shape of each region are substantially the same as in the first to third embodiments. Hereinafter, other arrangement examples of the exciting coils in which the shape of each exciting coil and the shape of each region are substantially the same will be shown.

  First, referring to FIG. 7 to FIG. 9, similar to the arrangement example of FIG. 1, an arrangement example in which the respective excitation coils are arranged adjacently and in a plane is shown.

  7 and 8 show examples of arrangement using triangular coils. In the arrangement example of FIG. 7, six triangular coils T1 to T6 are arranged so as to share one vertex of each, and the shape of the entire exciting coil group 31 is a parallel hexagonal shape in which three pairs of opposite sides are parallel and equal. (Parallel hexagon). Further, in the arrangement example of FIG. 8, the triangular coils T1 and T2, T3 and T4, T5 and T6, and T7 and T8 are arranged adjacent to each other so as to form parallelograms. The shape is a parallelogram combining the four parallelograms. When the shape of each triangular coil is a regular triangle, the entire shape of the exciting coil group 31 in the arrangement example of FIG. 7 is a regular hexagon, and the entire shape of the exciting coil group 31 in the arrangement example of FIG. Become.

  FIG. 9 shows an arrangement example using regular hexagonal coils. As shown in FIG. 9, the seven regular hexagonal coils H1 to H7 are adjacently arranged in a honeycomb shape.

  Note that each of the rectangular coil, the triangular coil, and the regular hexagonal coil has a shape that can be filled with a flat surface that can be spread without gaps. Among these, the rectangular coil used in the arrangement example of FIG. 1 is suitable for scanning the inspection object 9 side or the detection coil 11 side in the x0 (x1) direction and the y0 (y1) direction. In addition, the regular hexagonal coil used in the arrangement example of FIG. 9 has a shape that is closest to a circle among shapes that can be filled in a plane.

  Next, with reference to FIGS. 10 to 12, an arrangement example in which a part of each exciting coil is arranged in the same manner as in the arrangement examples of FIGS. 3 and 5 is shown.

  FIG. 10 shows an arrangement example in which 16 rectangular regions are formed by arranging two adjacent rectangular coils so as to overlap each other by approximately one half as in the arrangement example of FIG. 5. As shown in FIG. 10, the eight rectangular coils S1 to S8 are arranged so as to surround four of the sixteen rectangular regions S11 to S26 that are circled. Therefore, in the arrangement example of FIG. 10, an average (16 ÷ 8 =) 2 regions are formed per detection coil. Note that the rectangular coil surrounding the rectangular regions S16, S17, S20, and S21 is not necessary.

  FIG. 11 shows another arrangement example in which 16 rectangular regions are formed using eight rectangular coils, similarly to the arrangement example of FIG. As shown in FIG. 11, the eight rectangular coils R1 to R8 are shaped so as to surround four of the 16 rectangular regions S11 to S26 in one vertical row or one horizontal row, respectively. Similar to the arrangement example of FIG. 10, in the arrangement example of FIG. 11, an average of two regions per detection coil is formed.

  FIG. 12 shows an arrangement example using regular hexagonal coils. As shown in FIG. 12, the six regular hexagonal coils H1 to H6 are arranged so as to surround three of the twelve rhombus regions R11 to R16 and R21 to R26, each of which is circled. Has been. Accordingly, in the arrangement example of FIG. 12, an average (12 ÷ 6 =) 2 regions are formed per detection coil. In addition, the shape of each rhombus area | region is a rhombus which has an area of 1/3 of a regular hexagonal coil, and is formed by connecting every other three apexes of a regular hexagonal coil, and a gravity center.

  As described above, any one of a plurality of exciting coils is sequentially selected, and an alternating magnetic field that induces an eddy current from the selected exciting coil to the inspection object 9 is generated, and is generated by the eddy current. By calculating the magnetic field distribution for each region based on the measured magnetic field data Hq corresponding to the magnetic field H2 to be performed, the spatial resolution of the nondestructive inspection apparatus can be improved without increasing the number of magnetic sensors.

  Further, by making the shape of each region formed in the exciting coil group 31 substantially the same, it is not necessary to correct weighting or the like in the data processing unit 2, and the processing speed can be improved.

  In addition, by using a plurality of substantially the same rectangular coils as excitation coils and arranging them in a plane adjacent to each other, the inspection object 9 side or the detection coil 11 side is arranged in the x0 (x1) direction and y0 (y1). A configuration suitable for scanning in the direction can be obtained.

  Further, by using a plurality of substantially identical triangular coils as the exciting coils and arranging them in a plane adjacent to each other, the coil surface of the entire exciting coil group 31 can be spread without gaps.

  Further, by using a plurality of substantially identical regular hexagonal coils as the exciting coils and arranging them in a honeycomb shape, it is possible to spread the coil surface of the entire exciting coil group 31 without gaps with the exciting coil having a shape closest to a circle. it can.

  In addition, by arranging a part of the plurality of excitation coils included in the excitation coil group 31 in an overlapping manner, the number of excitation coils to be used is smaller than the number of regions, and the AC current supply unit 3 and the excitation coil group 31 can be easily connected. Can be wired.

  In addition, by using a plurality of substantially the same rectangular coils as the exciting coil and arranging a part of them overlapping each other, a plurality of substantially the same rectangular regions can be formed, and the inspection object 9 side or the detection coil can be formed. A configuration suitable for scanning the 11 side in the x0 (x1) direction and the y0 (y1) direction can be obtained.

  In addition, among the four rectangular coils that are substantially the same, two adjacent ones are arranged so as to overlap each other by approximately one half, thereby nine rectangles having an area of approximately one quarter of the rectangular coils. Regions can be formed.

  Further, any one of a plurality of exciting coils is sequentially selected by the DEMUX 33, and an eddy current is induced in the inspection object 9 by supplying an alternating current from the alternating current generating unit 32 to the selected exciting coil. The alternating magnetic field to be generated can be sequentially generated from a plurality of exciting coils.

  In addition, by sequentially selecting any one of a plurality of excitation coils in accordance with the count value CN output from the counter 34, the measured magnetic field data Hq and the count value indicating the excitation coil in which an alternating current flows. Based on CN, the distribution for each region of the magnetic field H2 generated by the eddy current can be calculated.

  In addition, the said embodiment is for making an understanding of this invention easy, and is not for limiting and interpreting this invention. The present invention can be changed and improved without departing from the gist thereof, and the present invention includes equivalents thereof.

  Although the case where the sensor unit 1 includes the SQUID has been described in the above embodiment, the present invention is not limited to this. The sensor unit 1 may include an FG sensor and an MI sensor in addition to the SQUID.

  In the above embodiment and the arrangement example of the excitation coils, the size of the entire excitation coil group 31 is equal to the total size of the regions having substantially the same area. However, the present invention is not limited to this. The exciting coil group 31 may be configured to include a non-use region other than a region having substantially the same area.

DESCRIPTION OF SYMBOLS 1 Sensor part 1a-1i Sensor part 2 Data processing part 3, 4 AC current supply part 9 Inspection object 11 Detection coil 11a-11i Detection coil 31 Excitation coil group 31a-31i Excitation coil 31r-11u Excitation coil 32 AC generation part 33 DEMUX (demultiplexer)
34 Counter 41 Excitation coil 91 Discontinuous part

Claims (7)

Including a plurality of exciting coils having a smaller number than the plurality of regions, which are arranged so as to overlap with each other so as to form a plurality of regions having substantially the same shape, and sequentially selecting any one of the plurality of exciting coils. A magnetic field generator that selects and generates an alternating magnetic field that induces eddy currents in the inspection object;
A magnetic sensor that outputs measurement magnetic field data corresponding to the magnetic field generated by the eddy current;
A data processing unit for obtaining a magnetic field generated by the eddy current for each of the plurality of regions based on the measured magnetic field data;
A nondestructive inspection apparatus characterized by comprising: 2. The nondestructive non-destructive device according to claim 1 , wherein the plurality of exciting coils are a plurality of substantially the same rectangular coils that are partially overlapped to form a plurality of substantially the same rectangular regions. Inspection device. The plurality of exciting coils include four substantially identical rectangular coils that are partially overlapped so as to form nine rectangular regions each having an approximately quarter area. The nondestructive inspection device according to claim 2 .   The plurality of exciting coils include eight substantially identical rectangular coils that are partially overlapped so as to form 16 rectangular regions each having an approximately quarter area. The nondestructive inspection device according to claim 2.   The plurality of exciting coils are substantially the same six regular hexagonal coils that are partially overlapped so as to form 12 rhombus regions each having an approximately one-third area. The nondestructive inspection apparatus according to claim 1. The magnetic field generator is
An AC generator that generates an AC current;
A demultiplexer that sequentially selects any one of the plurality of exciting coils and supplies the alternating current;
Nondestructive inspection apparatus according to any one of claims 1 to 5, further comprising a. The magnetic field generator further includes a counter that outputs a count value that sequentially increases or decreases,
The demultiplexer sequentially selects any one of the plurality of exciting coils according to the count value,
The nondestructive inspection apparatus according to claim 6 , wherein the data processing unit obtains a magnetic field generated by the eddy current for each of the plurality of regions based on the measured magnetic field data and the count value.

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