JP2014160056A - Inspection method and inspection device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an inspection method and an inspection device capable of improving the sensitivity and accuracy of the inspection by suppressing the attenuation of an ultrasonic guide wave.SOLUTION: A storage part 12 is previously stored with a relationship between a product of the frequency of an ultrasonic wave guide and a radius of a cylindrical-shaped structure and a product of an attenuation factor per unit length of the structure of the ultrasonic wave guide and the radius of the structure. A determination part 13 receives the mode and frequency of the ultrasonic guide wave used for the inspection which is determined based on the radius of the structure to be detected and the relationship stored in the storage part 12. Thereby, the attenuation of the ultrasonic guide wave can be suppressed, and a distance that can be inspected becomes long, and the sensitivity of the inspection can be improved. As a result, the accuracy of the inspection can be improved.

Description

  The present invention relates to an inspection method and an inspection apparatus, and more particularly to a nondestructive inspection method and a nondestructive inspection apparatus using an ultrasonic guided wave.

  Conventionally, there has been an ultrasonic flaw detection method for detecting scratches, defects, thinning, etc. of various structures or searching for specific structures by transmitting ultrasonic waves into structures and receiving reflected waves. Are known. The ultrasonic guided wave used in this ultrasonic flaw detection method is advantageous for long-distance inspection because the attenuation of the wave due to distance is smaller than the ultrasonic bulk wave propagating in a spherical wave shape in the medium. It is used for various inspection techniques such as inspection of pipes using the law (see Non-Patent Document 1, for example).

Shunpei Kameyama, others, guided wave flaw detection system, Japan Nondestructive Inspection Association, Nondestructive Inspection, Vol. 52, No. 12, 672-678, issued on December 1, 2003 Brian Pavlakovic, Mike Lowe, David Alleyne, and Peter Cawley, “Disperse: a general purpose program for creating dispersion curves”, Review of Progress in Quantitative Nondestructive Evaluation, edited by DO Thompson and DE Chimenti, Plenum Press, New York, Vol. 16, pp. 185-192, 1997

  The ultrasonic guided wave can be propagated over a long distance because the energy of the wave is almost completely confined in the structure installed in the air, so that the distance attenuation is small and can be propagated over a long distance. Can be used for a wide range of inspections.

  However, since the ultrasonic guide wave has a small difference in density when the structure is embedded in a solid, generally, the vibration energy leaks to the surrounding medium, resulting in a large attenuation. I was sorry.

  For example, since wave energy leaks into the soil around the structure embedded in the ground or the like, the attenuation in the structure is greater than in the air. For this reason, the inspectable distance is shortened. Further, since the signal strength is relatively reduced even within the inspectable distance, the sensitivity and accuracy of the inspection are lowered due to the deterioration of the SN ratio.

  Accordingly, an object of the present invention is to provide an inspection method and an inspection apparatus that can improve the sensitivity and accuracy of inspection by suppressing attenuation of an ultrasonic guide wave.

  In order to solve the above-described problems, an inspection method according to the present invention includes a frequency of an ultrasonic guided wave, a parameter representing a cross-sectional shape perpendicular to the longitudinal direction of a long structure, and an embedded in a medium. The relationship between the attenuation rate when the ultrasonic guide wave is propagated in the longitudinal direction of the structure and the length of the ultrasonic wave guide wave prepared in advance for each mode of the ultrasonic guide wave and the length embedded in the medium to be inspected Determining a mode and frequency of an ultrasonic guide wave used for inspection based on a value of a parameter representing a cross-sectional shape perpendicular to the longitudinal direction of the structure of the scale and a relationship prepared in advance, and the determined mode and frequency And a step of inspecting a structure to be inspected using the ultrasonic guided wave.

  In the above inspection method, the structure is a cylindrical pipe or a cylindrical solid rod embedded in the ground, the parameter is the radius of the cylinder or the cylinder, and the relationship is the frequency of the ultrasonic guide wave. The relationship between the product of the radius and the product of the attenuation factor and the radius may be used.

  In the inspection method, the relationship may be prepared in advance for each material of the structure.

  In the above inspection apparatus, the structure is a steel cylindrical solid rod structure embedded in the ground, and the mode of the ultrasonic guided wave is L (0, 1) or L (0, 2). ) Mode and the frequency of the ultrasonic guided wave is the product of the frequency of the ultrasonic guided wave and the radius of the cross section perpendicular to the longitudinal direction of the cylindrical solid rod structure in the L (0, 1) mode. Is selected from the range of 1 kHz · m or less, and in the L (0,2) mode, the product of the frequency of the ultrasonic guide wave and the radius of the cross section perpendicular to the longitudinal direction of the cylindrical solid rod structure is 2 It may be selected from a range of ˜3 kHz · m.

  In the above inspection apparatus, the structure is an aluminum cylindrical solid rod structure embedded in the ground, and the mode of the ultrasonic guided wave is L (0, 1) or L (0, 2). ) Mode and the frequency of the ultrasonic guided wave is the product of the frequency of the ultrasonic guided wave and the radius of the cross section perpendicular to the longitudinal direction of the cylindrical solid rod structure in the L (0, 1) mode. Is selected from the range of 1 kHz · m or less, and in the L (0,2) mode, the product of the frequency of the ultrasonic guide wave and the radius of the cross section perpendicular to the longitudinal direction of the cylindrical solid rod structure is 2 You may make it select from the range of 0.0-2.5 kHz * m.

  In the inspection apparatus, the structure is a steel cylindrical solid rod structure embedded in the ground, and the ultrasonic guided wave mode is T (0,2) mode. As the frequency of the guide wave, the product of the frequency of the ultrasonic guide wave and the radius of the cross section perpendicular to the longitudinal direction of the cylindrical solid rod structure may be selected from the range of 4 to 8 kHz · m.

  In the inspection apparatus, the structure is a steel cylindrical solid rod structure embedded in the ground, and the mode of the ultrasonic guide wave is F (1, m) mode. In the case of the first mode, the frequency of the guide wave is 1.0 to 1.2 kHz · m, which is the product of the frequency of the ultrasonic guide and the radius of the cross section perpendicular to the longitudinal direction of the cylindrical solid rod structure. In the case of the second mode, the product of the frequency of the ultrasonic guide and the radius of the cross section perpendicular to the longitudinal direction of the cylindrical solid rod structure is in the range of 1.7 to 2.1 kHz · m. In the case of the third mode, the product of the frequency of the ultrasonic guide and the radius of the cross section perpendicular to the longitudinal direction of the cylindrical solid rod structure is in the range of 3.1 to 3.5 kHz · m. It may be selected.

  The inspection apparatus according to the present invention includes an ultrasonic guide wave in the longitudinal direction of a structure embedded in a medium, a parameter representing the frequency of the ultrasonic guide wave, a cross-sectional shape perpendicular to the longitudinal direction of the long structure. The relationship with the attenuation factor when propagating the wave is stored in advance for each mode of the ultrasonic guided wave, and the longitudinal direction of the long structure embedded in the medium to be inspected A determination unit that determines the mode and frequency of the ultrasonic guide wave used for the inspection based on the parameter value representing the cross-sectional shape and the relationship prepared in advance, and the inspection using the ultrasonic guide wave of the determined mode and frequency And an inspection unit that inspects a target structure.

  According to the present invention, the frequency of the ultrasonic guided wave, the parameter indicating the cross-sectional shape perpendicular to the longitudinal direction of the long structure, and the ultrasonic guided wave propagate in the longitudinal direction of the structure embedded in the medium. A parameter representing the cross-sectional shape perpendicular to the longitudinal direction of a long structure embedded in a medium to be inspected, which is stored in advance for each ultrasonic guided wave mode, and the relationship with the attenuation factor when By determining the mode and frequency of the ultrasonic guide wave used for the inspection based on the value of and the relationship prepared in advance, it is possible to use an ultrasonic guide wave with low attenuation. Sensitivity and accuracy can be improved.

FIG. 1 is a diagram for explaining the state of an inspection apparatus used in an inspection method according to an embodiment of the present invention and a structure to be inspected by the inspection apparatus. FIG. 2 is a block diagram showing a configuration of the inspection apparatus of FIG. FIG. 3 is a flowchart showing the inspection method according to the embodiment of the present invention. FIG. 4 is a diagram illustrating an example of a simulation result when an L-mode ultrasonic guide wave is propagated to a long member made of steel. FIG. 5 is a diagram showing an example of a simulation result when an L-mode ultrasonic guide wave is propagated to a long member made of aluminum. FIG. 6 is a diagram illustrating an example of a simulation result when a T-mode ultrasonic guide wave is propagated to a long member made of steel. FIG. 7 is a diagram illustrating an example of a simulation result when an F-mode ultrasonic guide wave is propagated to a long member made of steel.

  Hereinafter, an inspection method according to an embodiment of the present invention will be described in detail with reference to the drawings.

<Configuration of inspection device>
As shown in FIG. 1, the inspection apparatus 1 used in the inspection method according to the present embodiment is thinned, flaw-detected, etc. with respect to a cylindrical or columnar long structure 10 having a radius r embedded in the ground. The state of the structure 10 is inspected. As shown in FIG. 2, the inspection apparatus 1 includes an input unit 11, a storage unit 12, a determination unit 13, a transmission / reception unit 14, an inspection unit 15, and an output unit 16.

  The input unit 11 accepts various types of information used for inspection of the inspection apparatus 1 input from the outside. The various types of information include information regarding the material and radius of the structure 10 to be inspected and the ultrasonic guide mode for propagating the structure 10. Various pieces of input information are output to the determination unit 13.

  The storage unit 12 stores in advance various information used for inspection by the inspection apparatus 1. The various information includes the frequency of the ultrasonic guide wave, the parameter representing the cross-sectional shape perpendicular to the longitudinal direction of the long structure 10, and the ultrasonic guide wave in the longitudinal direction of the structure 10 embedded in the ground. The relationship with the attenuation factor when propagating the signal is included. In the present embodiment, this relationship consists of the product of the frequency of the ultrasonic guide wave and the radius of the cylindrical structure 10 and the product of the attenuation factor and the radius of the structure 10.

  The determination unit 13 receives the frequency of the ultrasonic guide wave to be transmitted from the transmission / reception unit 14, which is determined based on the information input from the input unit 11 and the relationship stored in the storage unit 12. Details of the frequency determination method will be described later. The determined frequency is output to the transmission / reception unit 14.

  As shown in FIG. 1, the transmitter / receiver 14 drives a probe 141 fixed at an arbitrary position of the structure 10 to be measured, and drives the probe 141 and is detected by the probe 141. And a transmission / reception circuit 142 for outputting a signal to the inspection unit 15.

  The probe 141 can be realized, for example, by an array of piezoelectric elements that transmit and receive ultrasonic waves. The probe 141 is attached to, for example, a portion exposed on the ground surface of a metal bar embedded in the soil, and the structure 10 from a position fixed to the structure 10 based on an instruction from the transmission / reception circuit 142. A wave packet of an ultrasonic guide wave propagating in the extending direction is transmitted, and an echo reflected by the end of the structure 10 or the like is received.

The transmission / reception circuit 142 includes a waveform generator that generates an arbitrary waveform based on the selection result by the determination unit 13, a power amplification circuit that drives the piezoelectric element of the probe 141 based on the waveform, and the probe 141. And a receiving amplifier that amplifies the signal of the elastic wave received.
In the present embodiment, the waveform generator generates a waveform of an ultrasonic guide wave having a frequency specified by the selection result by the determination unit 13. Then, the power amplifier circuit drives the piezoelectric element of the probe 141 based on the waveform. As a result, an ultrasonic guide wave having a frequency specified by the selection result by the determination unit 13 propagates to the structure 10 to which the probe 141 is attached.

  The inspection unit 15 inspects the state of the structure 10 by performing signal processing corresponding to the inspection content of the structure 10 on the signal received by the probe 141.

  The output unit 16 outputs the inspection result by the inspection unit 15 to a monitor or the like.

<Inspection method>
Next, the inspection method according to the present embodiment will be described with reference to FIG.

  First, the user prepares in advance a relationship between the product of the frequency of the ultrasonic guide wave and the radius of the cylindrical structure 10 and the product of the attenuation factor and the radius of the structure 10 (step S1).

When the ultrasonic guided wave propagates through the long structure 10 embedded in the ground, the surface of the structure 10 is vibrated along with the propagation, so that an elastic wave is radiated into the medium around the structure 10. As a result of the energy loss due to the elastic waves radiated to the surroundings, the amplitude gradually decreases with propagation. The frequency dependence of the attenuation can be calculated by generally available simulation software (see Non-Patent Document 2, for example). Examples of relationships obtained as a result of such calculations are shown in FIGS. FIG. 4 shows an ultrasonic wave in a longitudial mode (hereinafter referred to as “L mode”) in which a wave is displaced symmetrically with respect to the tube axis in a steel cylindrical solid rod structure embedded in the soil. The relationship between the attenuation rate per unit length and the radius product (vertical axis) and the product of frequency and radius (horizontal axis) when the guide wave is propagated is shown. FIG. 5 shows the product (vertical axis) and frequency of attenuation factor and radius per unit length when an L-mode ultrasonic guided wave is propagated through an aluminum cylindrical solid rod structure embedded in the soil. And the product of the radii (horizontal axis). FIG. 6 shows an ultrasonic guided wave in a torsional mode (hereinafter referred to as “T mode”) in which a wave is twisted and displaced in a circumferential direction on a steel cylindrical solid rod structure embedded in soil. The relationship between the attenuation rate per unit length and the product of radius (vertical axis) and the product of frequency and radius (horizontal axis) when propagated is shown. FIG. 7 shows an ultrasonic guided wave in a flexural mode (hereinafter referred to as “F mode”) in which a wave is displaced asymmetrically with respect to the tube axis in a steel cylindrical solid rod structure embedded in the soil. The relationship between the product of attenuation and unit radius (vertical axis) and the product of frequency and radius (horizontal axis) is shown.
Here, the vertical axis represents the product [db · m / m] of the attenuation rate [db / m] of each ultrasonic guide wave and the radius of the long member 10, and the horizontal axis represents the frequency and length of each ultrasonic guide wave. The product of the radius of the scale member 10 [kHz · m] is shown. In addition, the physical property values shown in Table 1 are used for the density of soil and steel in the calculation of the relationships shown in FIGS. Similarly, the physical property values shown in Table 2 are used for the density of soil and aluminum in the calculation of the relationship shown in FIG.

The calculation range shown in FIG. 4, that is, the product of the attenuation factor and the radius is 0.00 to 1.40 [db · m / m], and the product of the frequency and the radius is 0.00 to 3.50 [kHz · m]. , There are three L modes, L (0,1), L (0,2) and L (0,3), which have different displacements in the radial direction. The L (0,1) mode and the L ( In the (0, 2) mode, there is a region where the attenuation rate is minimized.
For the L (0, 1) mode ultrasonic guide wave, it can be seen that within this calculation range, there is a region where the attenuation factor is minimum in a region where the product of the frequency and the radius is about 1 [kHz · m] or less. . Therefore, by determining the frequency based on this region and the radius of the structure 10 and using the L (0, 1) mode ultrasonic guide wave having this frequency, attenuation of the ultrasonic guide wave is suppressed. As a result, the inspection accuracy can be improved.
For the L (0, 2) mode ultrasonic guide wave, there is a region where the attenuation factor is minimum in the region where the product of the frequency and the radius is about 2 to 3 [kHz · m] within this calculation range. I understand that. Therefore, by determining the frequency based on this region and the radius of the structure 10, and using the L (0, 2) mode ultrasonic guide wave having this frequency, attenuation of the ultrasonic guide wave is suppressed. As a result, the inspection accuracy can be improved.

The calculation range shown in FIG. 5, that is, the product of the attenuation factor and the radius is 0.00 to 3.50 [db · m], and the product of the frequency and the radius is 0.00 to 3.00 [kHz · m]. , There are three L modes, L (0,1), L (0,2) and L (0,3), which have different displacements in the radial direction. The L (0,1) mode and L (0,3) 2) There is a region where the attenuation rate is minimum in the mode.
Among these, for the L (0, 1) mode ultrasonic guided wave, there is a region where the attenuation factor is minimum in the region where the product of the frequency and the radius is about 1 [kHz · m] or less within this calculation range. I understand that Therefore, by determining the frequency based on this region and the radius of the structure 10 and using the L (0, 1) mode ultrasonic guide wave having this frequency, attenuation of the ultrasonic guide wave is suppressed. As a result, the inspection accuracy can be improved.
For the L (0, 2) mode ultrasonic guided wave, there is a region where the attenuation factor is minimum in the region where the product of the frequency and the radius is about 2 to 2.5 [kHz · m] within this calculation range. You can see that it exists. Therefore, by determining the frequency based on this region and the radius of the structure 10, and using the L (0, 2) mode ultrasonic guide wave having this frequency, attenuation of the ultrasonic guide wave is suppressed. As a result, the inspection accuracy can be improved.

The calculation range shown in FIG. 6, that is, the product of the attenuation factor and the radius is 0.00 to 1.00 [db · m], and the product of the frequency and the radius is 0.0 to 8.0 [kHz · m]. , There are four T modes, T (0,1), T (0,2), T (0,3), and T (0,4), which have different displacements in the radial direction. ) There is a region where the attenuation rate is minimum in the mode.
It can be seen that the T (0, 2) mode ultrasonic guide wave has a region where the attenuation factor is minimum in a region where the product of the frequency and the radius is about 4 to 8 [kHz · m]. Therefore, by determining the frequency based on this region and the radius of the structure 10, and using the T (0, 2) mode ultrasonic guide wave having this frequency, attenuation of the ultrasonic guide wave is suppressed. As a result, the inspection accuracy can be improved.

The calculation range shown in FIG. 7, that is, the product of the attenuation factor and the radius is 0.00 to 0.80 [db · m / m], and the product of the frequency and the radius is 1.00 to 3.50 [kHz · m]. In this range, there are four F modes of F (1, m) with different displacements in the radial direction, and there are regions where the attenuation factor is minimum in the first to third F modes.
Among these, for the first F-mode ultrasonic guided wave, a region in which the product of the frequency and the radius is 1.0 to 1.2 [kHz · m] and the attenuation rate is minimum within this calculation range. It can be seen that exists. Accordingly, by determining the frequency based on this region and the radius of the structure 10 and using an F-mode ultrasonic guide wave having this frequency, attenuation of the ultrasonic guide wave is suppressed, so that the result As a result, the accuracy of the inspection can be improved.
For the second F-mode ultrasonic guided wave, there is a region where the attenuation factor is minimum in the region where the product of frequency and radius is 1.7 to 2.1 [kHz · m] within this calculation range. I understand that Accordingly, by determining the frequency based on this region and the radius of the structure 10 and using an F-mode ultrasonic guide wave having this frequency, attenuation of the ultrasonic guide wave is suppressed, so that the result As a result, the accuracy of the inspection can be improved.
For the third F-mode ultrasonic guided wave, there is a region where the attenuation factor is minimum in the region where the product of frequency and radius is 3.1 to 3.5 [kHz · m] within this calculation range. I understand that Accordingly, by determining the frequency based on this region and the radius of the structure 10 and using an F-mode ultrasonic guide wave having this frequency, attenuation of the ultrasonic guide wave is suppressed, so that the result As a result, the accuracy of the inspection can be improved.

  The relationship as described above may be stored in advance in the storage unit 12 for each material of the structure 10 and each mode of the ultrasonic guide.

  When the relationship is prepared, the user designates information on the material and radius of the structure 10 to be inspected and information on the mode of the ultrasonic guide for propagating the structure 10 via the input unit 11 (step S2).

When information on the material and radius of the structure 10 to be inspected and information on the mode of the ultrasonic guide for propagating the structure 10 are specified, the user can use the specified information and the relationship stored in the storage unit 12. Based on this, the frequency of the ultrasonic guide for propagating the structure 10 is determined (step S3).
Specifically, first, a corresponding relationship is extracted from the storage unit 12 based on information regarding the material of the designated structure 10 and the mode of the ultrasonic guide for propagating the structure 10. Subsequently, based on the extracted relationship and the radius of the structure 10 input from the input unit 11, the mode and frequency of the ultrasonic guide wave that minimizes the attenuation rate are determined.

For example, when the material of the structure 10 is steel, the radius of the structure 10 is 0.05 [m], and the mode of the ultrasonic guided wave to be propagated is the L mode, the user can, for example, make steel from the storage unit 12. FIG. 4 is extracted to show the relationship between the attenuation rate per unit length, the product of the radius, the product of the frequency and the radius when the L-mode ultrasonic guide wave is propagated to the cylindrical solid rod structure. According to FIG. 4, in the ultrasonic guide wave in the L (0, 1) mode, it can be seen that there is a region where the attenuation factor is minimum in a region where the product of the frequency and the radius is about 1 [kHz · m] or less. . Therefore, the user determines that the L-mode guide wave having the minimum attenuation rate is L (0, 1) mode and the frequency is about 20 [kHz] or less from the following equation (1). This result is received by the determination unit 13 and input to the transmission / reception unit 14.
Note that the attenuation rate α per unit length at this time is, as shown in FIG. 4, the product of the attenuation rate per unit length and the radius is about 0.1 [dB · m / m]. From (2), it is about 2 [dB / m].

1 ≧ 0.05 × f (1)
0.1 ≒ 0.05 × α (2)

For example, when the material of the structure 10 is aluminum, the radius of the structure 10 is 0.05 [m], and the mode of the ultrasonic guided wave to be propagated is the L mode, the user is, for example, an aluminum cylinder FIG. 5 shows the relationship between the attenuation rate per unit length, the product of the radius, the product of the frequency and the radius when the L-mode ultrasonic guide wave is propagated through the solid rod. According to FIG. 5, in the ultrasonic guide wave of the L (0, 1) mode, it can be seen that there is a region where the attenuation factor is minimum in a region where the product of the frequency and the radius is about 1 [kHz · m] or less. . Therefore, the user determines that the L-mode ultrasonic guided wave having the minimum attenuation rate is the L (0, 1) mode and the frequency is about 20 [kHz] or less from the following equation (3). This result is received by the determination unit 13 and input to the transmission / reception unit 14.
The attenuation rate α at this time is about 7 [dB / m from the following equation (4) because the product of the attenuation rate and the radius is about 0.35 [dB · m / m] with reference to FIG. ].

1 ≧ 0.05 × f (3)
0.35≈0.05 × α (4)

For example, when the material of the structure 10 is steel, the radius of the structure 10 is 0.05 [m], and the mode of the ultrasonic guided wave to be propagated is the T mode, the user can, for example, FIG. 6 is extracted to show the relationship between the attenuation rate per unit length, the product of the radius, the product of the frequency and the radius when the T-mode ultrasonic guide wave is propagated through the cylindrical solid rod made of steel. According to FIG. 6, in the ultrasonic guide wave of T (0,2) mode, it can be seen that there is a region where the attenuation factor is minimum in a region where the product of the frequency and the radius is about 4 [kHz · m] or more. . Therefore, the user determines that the T-mode ultrasonic guide wave having the minimum attenuation rate has a T (0, 2) mode and a frequency of about 80 [kHz] or higher in the following equation (5). This result is received by the determination unit 13 and input to the transmission / reception unit 14.
Note that the attenuation rate α at this time is about 0.18 [dB · m / m] as the product of the attenuation rate per unit length and the radius when referring to FIG. 3.6 [dB / m].

4 ≧ 0.05 × f (5)
0.18≈0.05 × α (6)

For example, when the material of the structure 10 is steel, the radius of the structure 10 is 0.05 [m], and the mode of the ultrasonic guided wave to be propagated is the F mode, the user can, for example, FIG. 7 shows the relationship between the attenuation rate per unit length, the product of the radius, the product of the frequency and the radius when the F-mode ultrasonic guide wave is propagated through the steel solid cylindrical rod. According to FIG. 7, in the F (1, m) mode ultrasonic guided wave, there is a region where the attenuation factor is minimum in the region where the product of the frequency and the radius is 1.7 to 2.1 [kHz · m]. I understand that Therefore, the user determines that the F-mode ultrasonic guide wave having the minimum attenuation rate is the second mode and the frequency is about 40 [kHz] from the following equation (7). This result is received by the determination unit 13 and input to the transmission / reception unit 14. In the following formula (7), 2 [kHz · m] is used as the product of the frequency and the radius, but the product of the frequency and the radius is in the range of 1.7 to 2.1 [kHz · m]. Therefore, any value in the range of 34 to 42 [kHz] can be used as the frequency.
Note that the attenuation rate α at this time is about 0.3 [dB · m / m] as the product of the attenuation rate per unit length and the radius when referring to FIG. 6 [dB / m].

2 ≒ 0.05 × f (7)
0.3 ≒ 0.05 × α (8)

  When the ultrasonic guide wave mode and frequency are input, the transceiver 14 drives the probe 141 so that the ultrasonic guide wave of the mode and frequency is transmitted, and the ultrasonic guide wave is transmitted to the structure. The probe 141 receives a signal such as an echo reflected from the end of 10 (step S4). The received signal is output to the inspection unit 15.

  The inspection unit 15 inspects the state of the structure 10 by performing signal processing corresponding to the inspection content of the structure 10 on the signal input from the transmission / reception unit 14 (step S5). The inspection result is output to the output unit 16 and displayed on the monitor or the like by the output unit 16 (step S6).

  As described above, according to the present embodiment, the relationship between the product of the frequency of the ultrasonic guided wave and the radius of the cylindrical structure 10 and the product of the attenuation factor and the radius of the structure 10 are determined in advance. Decrease in attenuation by determining the mode and frequency of the ultrasonic guided wave used for inspection based on the radius of the structure 10 to be inspected and stored in the storage unit 12 and based on the relationship stored in the storage unit 12 Since the ultrasonic guide can be used, the inspectable distance can be increased and the sensitivity of the inspection can be improved. As a result, the accuracy of the inspection can be improved.

  In the present embodiment, the case where a long member having a circular cross-sectional shape such as a cylindrical solid rod is used as the structure 10 has been described as an example. However, the cross-sectional shape of the structure 10 is limited to a circular shape. For example, a polygon such as a triangle or a quadrangle, or a two-dimensional shape such as an H shape or an I shape can be set as appropriate. In this case, the relationship between the value of the parameter representing each cross-sectional shape, the frequency of the ultrasonic guide wave, and the attenuation rate when the ultrasonic guide wave is propagated in the longitudinal direction of the structure embedded in the medium, This can be realized by preparing in advance for each mode of the ultrasonic guide wave.

  Further, in the present embodiment, a case where a cylindrical solid rod is used as the structure 10 and a radius is used as a parameter representing a cross-sectional shape perpendicular to the longitudinal direction of the structure 10 has been described as an example. When a cylindrical pipe is used as 10, at least one of the wall thickness, the inner diameter, and the outer diameter can be used as the parameter.

<Inspection method using inspection equipment>
Further, in the present embodiment, the case where the processes in steps S1 to S3 are performed by the user has been described. However, these processes may be performed by the inspection apparatus 1. This case will be described below.

  First, the relationship between the product of the frequency of the ultrasonic guide wave and the radius of the cylindrical structure 10 and the product of the attenuation factor and the radius of the structure 10 is prepared in advance and stored in the storage unit 12. (Step S1). At this time, the relationship may be stored in the storage unit 12 not only in the form of graphs as shown in FIGS. 4 to 7 but also in the form of functions.

  When starting the inspection, the input unit 11 first receives information on the material and radius of the structure 10 to be inspected and the mode of the ultrasonic guide for propagating the structure 10 based on the user's operation input (steps). S2). The received information is output to the determination unit 13.

When information on the material and radius of the structure 10 to be inspected and the ultrasonic guide mode for propagating the structure 10 are input from the input unit 11, the determination unit 13 stores the information and the storage unit 12. Based on the relationship, the frequency of the ultrasonic guide for propagating the structure 10 is determined (step S3).
Specifically, first, the determination unit 13 determines the corresponding relationship from the storage unit 12 based on the information on the material of the structure 10 and the mode of the ultrasonic guide propagating the structure 10 input from the input unit 11. Extract.
Subsequently, the determination unit 13 determines the mode and frequency of the ultrasonic guide wave with the minimum attenuation rate based on the extracted relationship and the radius of the structure 10 input from the input unit 11. This determination can be realized, for example, by performing image processing on the graph when the extracted relationship is in the form of a graph as shown in FIGS. Further, when the extracted relationship is stored in the form of a function, for example, it can be realized by calculating a minimum value from the function. Since specific examples of the ultrasonic guide wave mode and frequency determination method are the same as the above-described inspection method, the description thereof will be omitted.
The mode and frequency of the ultrasonic guide wave determined in this way are output to the transmission / reception unit 14.

  When the ultrasonic guide wave mode and frequency are input, the transmission / reception unit 14 drives the probe 141 so that the ultrasonic guide wave of the frequency is transmitted, and the ultrasonic guide wave is transmitted to the structure 10. A signal such as an echo reflected from the end or the like is received by the probe 141 (step S4). The received signal is output to the inspection unit 15.

  The inspection unit 15 inspects the state of the structure 10 by performing signal processing corresponding to the inspection content of the structure 10 on the signal input from the transmission / reception unit 14 (step S5). The inspection result is output to the output unit 16 and displayed on the monitor or the like by the output unit 16 (step S6).

  Thus, the storage unit 11 stores in advance the relationship between the product of the frequency of the ultrasonic guide wave and the radius of the cylindrical structure 10 and the product of the attenuation factor and the radius of the structure 10. Even if the determination unit 13 determines the mode and frequency of the ultrasonic guide wave used for inspection based on the radius of the structure 10 to be inspected and the relationship stored in the storage unit 12, the attenuation is small. Since the ultrasonic guide can be used, the inspectable distance can be increased and the sensitivity of the inspection can be improved. As a result, the accuracy of the inspection can be improved.

  The inspection apparatus 1 that realizes the above-described inspection method includes an arithmetic device such as a CPU (Central Processing Unit), a storage device such as a memory and an HDD (Hard Disc Drive), a keyboard, a mouse, a pointing device, a button, and a touch panel. An input device that detects input of information from the outside, an I / F (Interface) device that transmits and receives information from the outside, and a display device such as an LCD (Liquid Crystal Display) or an organic EL (Electro Luminescence) It consists of a computer equipped. That is, in the inspection apparatus 1, the hardware resource as described above is controlled by a program installed in the computer, and the hardware unit and the software cooperate to input the input unit 11, the storage unit 12, and the determination unit 13. The transmission / reception unit 14, the inspection unit 15, and the output unit 16 are realized.

  The present invention can be applied to various devices that transmit ultrasonic guide waves.

  DESCRIPTION OF SYMBOLS 1 ... Inspection apparatus, 10 ... Structure, 11 ... Input part, 12 ... Memory | storage part, 13 ... Determination part, 14 ... Transmission / reception part, 15 ... Inspection part, 16 ... Output part, 141 ... Probe, 142 ... Transmission / reception circuit .

Claims (8)

When the ultrasonic guide wave propagates in the longitudinal direction of the structure embedded in the medium, the frequency of the ultrasonic guide wave, the parameter representing the cross-sectional shape perpendicular to the longitudinal direction of the long structure Preparing a relationship with an attenuation factor in advance for each mode of the ultrasonic guide wave;
Ultrasonic guide wave mode used for inspection based on a parameter value representing a cross-sectional shape perpendicular to the longitudinal direction of a long structure embedded in the medium to be inspected and the relationship prepared in advance And determining a frequency;
And a step of inspecting the structure to be inspected using an ultrasonic guided wave having a determined mode and frequency. The inspection method according to claim 1,
The structure is a cylindrical pipe or a cylindrical solid rod embedded in the ground,
The parameter is the radius of the cylinder or cylinder;
The relation is a relation between a product of the frequency of the ultrasonic guide wave and the radius, and a product of the attenuation factor per unit length and the radius. In the inspection method according to claim 1 or 2,
The relation is prepared in advance for each material of the structure. In the inspection method according to claim 2 or 3,
The structure is a steel cylindrical solid rod structure embedded in the ground,
The ultrasonic guided wave mode is L (0, 1) or L (0, 2) mode,
In the L (0, 1) mode, the frequency of the ultrasonic guide wave is 1 kHz, which is the product of the frequency of the ultrasonic guide wave and the radius of the cross section perpendicular to the longitudinal direction of the cylindrical solid rod structure. In the case of the L (0, 2) mode selected from the range of m or less, the product of the frequency of the ultrasonic guide wave and the radius of the cross section perpendicular to the longitudinal direction of the cylindrical solid rod structure is 2 The inspection method is selected from a range of ˜3 kHz · m. In the inspection method according to claim 2 or 3,
The structure is an aluminum cylindrical solid rod structure embedded in the ground,
The ultrasonic guided wave mode is L (0, 1) or L (0, 2) mode,
In the L (0, 1) mode, the frequency of the ultrasonic guide wave is 1 kHz, which is the product of the frequency of the ultrasonic guide wave and the radius of the cross section perpendicular to the longitudinal direction of the cylindrical solid rod structure. In the case of the L (0, 2) mode selected from the range of m or less, the product of the frequency of the ultrasonic guide wave and the radius of the cross section perpendicular to the longitudinal direction of the cylindrical solid rod structure is 2 An inspection method characterized by being selected from a range of 0.0 to 2.5 kHz · m. In the inspection method according to claim 2 or 3,
The structure is a steel cylindrical solid rod structure embedded in the ground,
The ultrasonic guided wave mode is a T (0,2) mode,
The frequency of the ultrasonic guide wave is selected from a range in which the product of the frequency of the ultrasonic guide wave and the radius of the cross section perpendicular to the longitudinal direction of the cylindrical solid rod structure is 4 to 8 kHz · m. Inspection method characterized by In the inspection method according to claim 2 or 3,
The structure is a steel cylindrical solid rod structure embedded in the ground,
The mode of the ultrasonic guide wave is F (1, m) mode,
In the first mode, the frequency of the ultrasonic guide wave is 1.0 to 1 in the product of the frequency of the ultrasonic guide and the radius of the cross section perpendicular to the longitudinal direction of the cylindrical solid rod structure. In the case of the second mode, the product of the frequency of the ultrasonic guide and the radius of the cross section perpendicular to the longitudinal direction of the cylindrical solid rod structure is 1.7 to In the case of the third mode selected from the range of 2.1 kHz · m, the product of the frequency of the ultrasonic guide and the radius of the cross section perpendicular to the longitudinal direction of the cylindrical solid rod structure is 3.1. The inspection method is selected from the range of ~ 3.5 kHz · m. When the ultrasonic guide wave propagates in the longitudinal direction of the structure embedded in the medium, the frequency of the ultrasonic guide wave, the parameter representing the cross-sectional shape perpendicular to the longitudinal direction of the long structure A storage unit that stores a relationship with an attenuation factor in advance for each mode of the ultrasonic guide wave;
Ultrasonic guide wave mode used for inspection based on a parameter value representing a cross-sectional shape perpendicular to the longitudinal direction of a long structure embedded in the medium to be inspected and the relationship prepared in advance And a determining unit for determining a frequency,
An inspection apparatus comprising: an inspection unit that inspects the structure to be inspected using an ultrasonic guide wave having a determined mode and frequency.

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