JP7107438B2 - WIRE ROPE INSPECTION SYSTEM AND WIRE ROPE INSPECTION METHOD - Google Patents

Description

The present invention relates to a wire rope inspection system and a wire rope inspection method.

Conventionally, a wire rope inspection device for inspecting the condition of wire ropes is known. Such a configuration is disclosed, for example, in WO2018/138850.

The above-mentioned WO2018/138850 discloses an inspection device for inspecting the condition of a steel wire rope. This inspection device includes a detection coil for detecting changes in the magnetic field of the steel wire rope, and an electronic circuit section for determining whether the steel wire rope is flawed based on the signal from the detection coil.

WO2018/138850

However, the inspection device described in International Publication No. WO 2018/138850 can only determine the presence or absence of flaws in the steel wire rope, and cannot determine the type of flaw in the steel wire rope. In this case, the inspector needs to check the measurement data to determine the type of flaw in the steel wire rope, which makes it difficult to effectively support the maintenance work of the steel wire rope.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-described problems, and one object of the present invention is to detect the type of damage to a wire rope, thereby effectively assisting wire rope maintenance work. To provide a wire rope inspection system and a wire rope inspection method capable of performing

In order to achieve the above object, a wire rope inspection system according to a first aspect of the present invention comprises a detection coil for detecting changes in the magnetic field of the wire rope, and a control unit for controlling the detection of the type of damage to the wire rope. , based on the measurement data acquired by the detection coil, the control unit acquires smoothed data that is data obtained by smoothing the measurement data, and based on the acquired smoothed data, the base of the measurement data It is configured to acquire a line, acquire a peak waveform from the measurement data based on the acquired baseline, and perform control to detect the type of damage to the wire rope based on the acquired peak waveform. .

A wire rope inspection method according to a second aspect of the present invention includes the step of detecting a change in the magnetic field of the wire rope; a step of obtaining smoothed data that is the data that has been processed; a step of obtaining a baseline of the measured data based on the smoothed data; a step of obtaining a peak waveform from the measured data based on the baseline; and detecting the type of wire rope damage based on.

According to the present invention, as described above, the peak waveform is obtained from the measurement data based on the baseline, and the type of damage to the wire rope is detected based on the peak waveform. As a result, not only the presence or absence of damage to the wire rope, but also the type of damage to the wire rope can be detected and notified to the inspector. As a result, since it is not necessary for an inspector to check the measurement data to determine the type of damage to the wire rope, detecting the type of damage to the wire rope effectively assists maintenance work of the wire rope. be able to. In addition, as described above, by obtaining the peak waveform from the measurement data based on the baseline, unlike the case where the peak waveform is obtained without being based on the baseline, wire rope damage caused by wire rope damage An accurate peak waveform with reduced low-frequency components due to rope deformation can be obtained. As a result, the type of damage to the wire rope can be easily detected based on an accurate peak waveform in which low-frequency components due to deformation of the wire rope caused by damage to the wire rope are reduced.

1 is a schematic diagram showing the configuration of a wire rope inspection system according to one embodiment; FIG. 1 is a schematic diagram showing an elevator in which a wire rope inspected by a wire rope inspecting device according to one embodiment is used; FIG. 1 is a block diagram showing a control configuration of a wire rope inspection device according to one embodiment; FIG. It is a figure for demonstrating the structure of the magnetic field application part of the magnetic material inspection apparatus by one Embodiment, and a detection part. FIG. 4 is a diagram for explaining the overall configuration of wire rope damage type detection processing according to an embodiment; FIG. 4 is a diagram for explaining similarity acquisition processing between a peak waveform and a reference peak waveform according to one embodiment; FIG. 10 is a diagram for explaining a representative value acquisition process in a similarity acquisition process between a peak waveform and a reference peak waveform according to one embodiment; FIG. 10 is a diagram for explaining details of a similarity obtaining process between a peak waveform and a reference peak waveform according to one embodiment; FIG. 10 is a diagram for explaining a process of obtaining an appearance order between positive and negative peak waveforms according to one embodiment; FIG. 4 is a diagram for explaining a process of acquiring the number of peak waveforms between positive and negative peak waveforms according to one embodiment; FIG. 4 is a diagram for explaining a process of acquiring parameters of a peak waveform according to one embodiment; FIG. 10 is a diagram for explaining a process for detecting the type of wire rope damage based on peak waveform parameters according to one embodiment; FIG. 10 is a diagram for explaining a process of detecting the type of wire rope damage based on the similarity of peak waveforms and the parameters of the peak waveforms according to one embodiment; It is a figure for demonstrating the data processing system of the wire rope inspection apparatus by one Embodiment. 4A is a diagram showing a state in which measured data is stored in a first memory and measured data stored in a second memory is output to a control unit in the data processing system according to the embodiment; FIG. (B) is a diagram showing a state in which measured data is stored in the second memory and the measured data stored in the first memory is output to the control unit in the data processing system according to the embodiment.

Embodiments embodying the present invention will be described below with reference to the drawings.

First, the overall configuration of a wire rope inspection system 100 according to one embodiment will be described with reference to FIGS. 1 to 4. FIG.

(Configuration of wire rope inspection system)
As shown in FIG. 1, a wire rope inspection system 100 is a system for inspecting a wire rope 101, which is an object to be inspected. The wire rope inspection system 100 includes a wire rope inspection device 200 that magnetically detects the state of the wire rope 101 and an external device 300 that displays the inspection results of the wire rope 101 . The wire rope inspection system 100 is configured to inspect damage to the wire rope 101 using a wire rope inspection device 200 and an external device 300 .

The wire rope 101 is formed by weaving (for example, strand weaving) a magnetic wire material. Wire rope 101 is, for example, a steel wire rope (steel wire rope). The wire rope 101 is a long magnetic body extending in the X direction. The wire rope 101 is monitored for its condition (presence or absence of scratches, etc.) in order to prevent disconnection due to deterioration. Then, the wire rope 101 whose deterioration has progressed beyond a predetermined amount is replaced.

(wire rope inspection device)
As shown in FIG. 2, the wire rope inspection device 200 inspects the wire rope 101 while relatively moving along the surface of the wire rope 101, which is the object to be inspected. The wire rope 101 is a moving rope that drives the elevator 400 . The elevator 400 includes a car portion 401, a hoist 402 that winds up the wire rope 101 to raise and lower the car portion 401, and a position sensor 403 that detects the position of the car portion 401 (the wire rope 101). Since the wire rope 101 is moved by the hoist 402 in the elevator 400, the inspection is performed as the wire rope 101 is moved while the wire rope inspection device 200 is fixed. The wire rope 101 is arranged so as to extend in the X direction at the position of the wire rope inspection device 200 .

As shown in FIG. 3 , the wire rope inspection device 200 includes a detection section 1 and an electronic circuit section 2 . The detector 1 includes a detector coil 10 which is a differential coil having a pair of receiver coils 11 and 12 and an excitation coil 13 . The electronic circuit section 2 includes a control section 21 , a reception I/F 22 , a storage section 23 , an excitation I/F 24 , a power supply circuit 25 and a communication section 26 . The wire rope inspection device 200 also includes a magnetic field applying section 4 (see FIG. 4).

An external device 300 is communicably connected to the wire rope inspection device 200 via the communication unit 26 .

As shown in FIG. 1 , the external device 300 includes a communication section 301 , a control section 302 , a display section 303 and a storage section 304 . The external device 300 is configured to receive data such as the results of detection of damage to the wire rope 101 by the wire rope inspection device 200 via the communication unit 301 . Further, the external device 300 is configured to display the detection result of damage to the wire rope 101 on the display unit 303 under the control of the control unit 302 . Further, the external device 300 is configured to store the detection result of the damage of the wire rope 101 and the like in the storage section 304 .

As shown in FIG. 4 , the wire rope inspection device 200 is configured to detect changes in the magnetic field (magnetic flux) of the wire rope 101 using the detection coil 10 . The wire rope inspection device 200 is configured so that no DC magnetizer is arranged near the coil.

(Structure of magnetic field application unit)
As shown in FIG. 4, the magnetic field applying unit 4 applies a magnetic field in advance to the wire rope 101, which is an object to be inspected, in the Y direction (the direction intersecting with the direction in which the wire rope 101 extends), and applies a magnetic field to the wire rope, which is a magnetic material. It is configured to align the magnetization magnitude and direction of 101 . Further, the magnetic field applying section 4 includes a first magnetic field applying section including magnets 41 and 42 and a second magnetic field applying section including magnets 43 and 44 . The first magnetic field application section (magnets 41 and 42) is arranged on one side (the X1 direction side) of the direction in which the wire rope 101 extends with respect to the detection section 1 . The second magnetic field applying section (magnets 43 and 44) is arranged on the other side (X2 direction side) of the direction in which the wire rope 101 extends with respect to the detecting section 1. As shown in FIG.

The first magnetic field applying section (magnets 41 and 42) is configured to apply a magnetic field in parallel to a plane intersecting the extending direction (X direction) of the wire rope 101 and in the Y2 direction. The second magnetic field applying units (magnets 43 and 44) are configured to apply a magnetic field in parallel to a plane intersecting the extending direction (X direction) of the wire rope 101 and in the Y1 direction. That is, the magnetic field applying unit 4 is configured to apply a magnetic field in a direction substantially orthogonal to the X direction, which is the longitudinal direction of the elongated material.

(Structure of detector)
Detector coil 10 (receiving coils 11 and 12) and excitation coil 13 are each wound a plurality of times along the longitudinal direction with the direction in which wire rope 101, which is a magnetic body made of a long material, extends as a central axis. ing. Also, the detector coil 10 and the excitation coil 13 are coils including conductor portions that are cylindrically formed along the X direction (longitudinal direction) in which the wire rope 101 extends. Therefore, the surfaces formed by the wire portions around which the detector coil 10 and the excitation coil 13 are wound are substantially perpendicular to the longitudinal direction. A wire rope 101 passes through the sensing coil 10 and the excitation coil 13 . Also, the detection coil 10 is provided inside the excitation coil 13 . Note that the arrangement of the detector coil 10 and the excitation coil 13 is not limited to this. The receiving coil 11 of the sensing coil 10 is arranged on the X1 direction side. Also, the receiving coil 12 of the detecting coil 10 is arranged on the X2 direction side. The receiving coils 11 and 12 are arranged with an interval of several millimeters to several centimeters.

The excitation coil 13 excites the magnetization state of the wire rope 101 . Specifically, when an exciting alternating current is supplied to the exciting coil 13, a magnetic field generated based on the exciting alternating current is applied inside the exciting coil 13 along the X direction.

A sensing coil 10 is configured to transmit a differential signal of a pair of receiving coils 11 and 12 . Specifically, the detection coil 10 is configured to detect changes in the magnetic field of the wire rope 101 and transmit differential signals. The detection coil 10 is configured to detect a change in the magnetic field in the X direction of the wire rope 101, which is an object to be inspected, and output a detection signal (voltage). That is, the detection coil 10 detects a change in the magnetic field in the X direction intersecting the Y direction with respect to the wire rope 101 to which the magnetic field applying unit 4 has applied the magnetic field in the Y direction. The detection coil 10 is also configured to output a differential signal (voltage) based on the detected change in the magnetic field of the wire rope 101 in the X direction. Further, the detection coil 10 is arranged so that substantially all of the magnetic field generated by the excitation coil 13 can be detected (inputted).

If the wire rope 101 has a defect (such as a flaw), the total magnetic flux (a value obtained by multiplying the magnetic field by the magnetic permeability and the area) of the wire rope 101 is reduced at the portion with the defect (such as the flaw). As a result, for example, when the receiving coil 11 is positioned at a location with a defect (such as a scratch), the amount of magnetic flux passing through the receiving coil 12 changes compared to that of the receiving coil 11, resulting in a difference in the voltage detected by the detecting coil 10. the absolute value of (differential signal) increases. On the other hand, the differential signal is substantially zero in a portion without defects (scratches, etc.). Thus, a clear signal (a signal with a good S/N ratio) representing the presence of a defect (such as a scratch) is detected in the detection coil 10 . Thereby, the electronic circuit section 2 can detect the presence of a defect (such as a flaw) in the wire rope 101 based on the value of the differential signal.

(Structure of electronic circuit section)
The control section 21 of the electronic circuit section 2 shown in FIG. 3 is configured to control each section of the wire rope inspection device 200 . Specifically, the control unit 21 includes a processor such as a CPU (Central Processing Unit), a memory, an AD converter, and the like.

The control unit 21 is configured to receive the differential signal from the sensing coil 10 and detect the state of the wire rope 101 . Further, the control unit 21 is configured to perform control to excite the excitation coil 13 . The control unit 21 is also configured to transmit the detection result of the state of the wire rope 101 to the external device 300 via the communication unit 26 .

The reception I/F 22 is configured to receive the differential signal from the sensing coil 10 and transmit it to the control section 21 . Specifically, the reception I/F 22 includes an amplifier. Also, the reception I/F 22 is configured to amplify the differential signal of the sensing coil 10 and transmit it to the control section 21 . The storage unit 23 includes a storage medium such as flash memory, and is configured to store information.

The excitation I/F 24 is configured to receive a control signal from the control section 21 and control power supply to the excitation coil 13 . Specifically, the excitation I/F 24 controls power supply from the power supply circuit 25 to the excitation coil 13 based on the control signal from the control section 21 .

(Detection of types of wire rope damage)
Next, processing for detecting the type of damage to the wire rope 101 will be described with reference to FIGS. 5 to 13. FIG.

In this embodiment, as shown in FIG. 5 , the control unit 21 is configured to perform control to detect the type of damage to the wire rope 101 based on the measurement data 201 acquired by the sensing coil 10 . The control unit 21 detects, as types of damage to the wire rope 101, wire breakage, fixed deformation due to external pressure (hereinafter simply referred to as "kink"), and loose twisting of the wire (hereinafter simply referred to as "hay"). It is configured to perform control to

Specifically, first, based on the measurement data 201 , the control unit 21 performs control to acquire smoothed data 202 (smoothing data) that is data obtained by smoothing the measurement data 201 . Specifically, the control unit 21 performs control to obtain smoothed data 202 by smoothing the measured data 201 with a low-pass filter. As a result, as smoothed data 202, data of fluctuation components (low-frequency components) caused by deformation of the wire rope due to damage to the wire rope is obtained.

Next, the control unit 21 controls acquisition of the baseline 203 of the measurement data 201 based on the acquired smoothed data 202 . Specifically, the control unit 21 performs control to acquire a line connecting intersections 202 a of the waveform of the measured data 201 and the waveform of the smoothed data 202 as the baseline 203 .

Next, the control unit 21 performs control to correct the measurement data 201 based on the acquired baseline 203 . Specifically, the control unit 21 performs correction by subtracting the baseline 203 from the measurement data 201 . That is, the control unit 21 performs correction by subtracting low frequency components from the measurement data 201 . As a result, the corrected measurement data 201 is obtained by removing the fluctuation component (low frequency component) caused by the deformation of the wire rope due to the damage to the wire rope.

Next, the control unit 21 performs control to acquire the peak waveform 204 based on the corrected measurement data 201 . Specifically, the control unit 21 performs control to acquire a group of measured values having a positive value with respect to the baseline 203 as a positive peak waveform 204 in the corrected measurement data 201 . In addition, the control unit 21 performs control to obtain a group of measured values having negative values with respect to the baseline 203 as a negative peak waveform 204 in the corrected measurement data 201 . The control unit 21 performs control to distinguish and acquire the positive peak waveform 204 and the negative peak waveform 204 . A peak waveform 204 is a high-frequency component of the measurement data 201 , such as a waveform component indicating damage to the wire rope 101 , which remains after correction by the baseline 203 .

Finally, the control unit 21 performs control to detect the type of damage to the wire rope 101 based on the acquired peak waveform 204 . Specifically, the control unit 21 compares the peak waveform 204 with a reference peak waveform 205 (case peak waveform) (similarity 206 to be described later), and a parameter 207 (peak index) that specifies the peak waveform 204. Based on, the control for detecting the type of damage to the wire rope 101 is performed.

<Detection of type of wire rope damage based on comparison with reference peak waveform>
As shown in FIG. 6, the control unit 21 detects damage to the wire rope 101 based on the comparison result between the peak waveform 204 and the reference peak waveform 205, which is a waveform for reference indicating the damage to the wire rope 101 of a specific type. Control to detect the type of The reference peak waveform 205 is a peak waveform obtained from known data, which is measurement data 201 in which the type of damage to the wire rope 101 is known, by the same processing as that for obtaining the peak waveform 204 . That is, the reference peak waveform 205 is obtained by obtaining smoothed data obtained by smoothing the known data based on the known data, which is the measurement data 201 in which the type of damage to the wire rope 101 is known. A peak waveform obtained from the known data based on the obtained baseline of the known data obtained by obtaining the baseline of the known data based on the smoothed data of the known data.

The reference peak waveform 205 is pre-stored in the storage unit 23 . The storage unit 23 stores, as the reference peak waveforms 205, a reference peak waveform 205a indicating wire breakage, a reference peak waveform 205b indicating a kink, and a reference peak waveform 205c indicating a wire break. The number of reference peak waveforms 205 for each damage (strand break, kink, crack) stored in the storage unit 23 may be one or more. The control unit 21 performs control to acquire a comparison result between the peak waveform 204 and each of the reference peak waveform 205a indicating wire breakage, the reference peak waveform 205b indicating kink, and the reference peak waveform 205c indicating hail.

Further, the control unit 21 performs control to obtain a similarity 206 between the peak waveform 204 and the reference peak waveform 205 as a comparison result between the peak waveform 204 and the reference peak waveform 205 . Then, the control unit 21 performs control to detect the type of damage to the wire rope 101 based on the acquired similarity 206 .

At this time, as shown in FIG. 7, the control unit 21 divides the peak waveform 204 by a predetermined number n, obtains representative values P1 to Pn for the predetermined number n, and obtains Based on the representative values P1 to Pn for a predetermined number n of the peak waveform 204 and the representative values SP1 to SPn for a predetermined number n of the reference peak waveform 205, the similarity 206 is obtained. I do. The predetermined number n is not particularly limited as long as it is a number smaller than the number of measured value groups forming the peak waveform 204, but can be about 7 to 9, for example. Also, the representative values SP1 to SPn of the reference peak waveform 205 can be stored in the storage unit 23 in advance.

Specifically, as shown in FIG. 8, the control unit 21 sets, as the degree of similarity 206, the vector of the peak waveform 204 represented by the representative values P1 to Pn and the reference peak waveform represented by the representative values SP1 to SPn. Control is performed to acquire the COS value of the angle θ formed with the vector 205 . The value of COS(θ) can be obtained by the formula shown in FIG. The larger the value of COS(θ) (ie, the smaller the angle θ), the greater the similarity 206, indicating that the peak waveform 204 and the reference peak waveform 205 are similar in shape. Also, the smaller the value of COS(θ) (that is, the larger the angle θ), the smaller the degree of similarity 206, indicating that the shapes of the peak waveform 204 and the reference peak waveform 205 are dissimilar. Note that COS(θ) is an example of the degree of similarity 206, and the method of obtaining the degree of similarity 206 is not limited to this method.

The control unit 21 controls each of a reference peak waveform 205a (see FIG. 6) indicating wire breakage, a reference peak waveform 205b (see FIG. 6) indicating a kink, and a reference peak waveform 205c (see FIG. 6) indicating a wire breakage. , and the peak waveform 204 are obtained. At this time, the control unit 21 performs control to acquire the similarity 206 for each of the positive and negative peak waveforms 204 . This is because when the sensing coil 10 is a differential coil, the waveform indicating damage to the wire rope 101 is a waveform including at least a pair of positive and negative peak waveforms.

Specifically, when the peak waveform 204 is a positive peak waveform 204, the positive peak waveform of the reference peak waveform 205a indicating wire breakage, the positive peak waveform of the reference peak waveform 205b indicating kink, The similarity 206 between each of the positive peak waveforms of the reference peak waveform 205 c shown and the peak waveform 204 is acquired by the control unit 21 . Similarly, when the peak waveform 204 is a negative peak waveform 204, the negative peak waveform of the reference peak waveform 205a indicating wire breakage, the negative peak waveform of the reference peak waveform 205b indicating kink, and the reference peak waveform 205b indicating breakage The similarity 206 between each of the negative peak waveforms of the peak waveform 205 c and the peak waveform 204 is acquired by the control unit 21 . If high similarity is obtained in both the positive peak waveform 204 and the negative peak waveform 204, there is a possibility that the damage of the wire rope 101 is the damage of the reference peak waveform 205 that obtained the high similarity.

Further, in the present embodiment, as shown in FIG. 9, when the control unit 21 acquires the positive peak waveform 204 and the negative peak waveform 204 with similarity higher than a predetermined value, the acquired Based on the appearance order of the positive peak waveform 204 and the negative peak waveform 204, control is performed to detect the type of damage to the wire rope 101. FIG. This is because the appearance order of the positive peak waveform 204 and the negative peak waveform 204 tends to differ depending on the type of damage to the wire rope 101 . Specifically, when the appearance order of the positive and negative peak waveforms 204 is the first order (in FIG. 9, the positive and negative order), there is a possibility that the type of damage to the wire rope 101 is kink or seam. Further, when the order of appearance of the positive and negative peak waveforms 204 is the second order (in FIG. 9, the order of negative and positive) that is the reverse order of the first order, the type of damage to the wire rope 101 is wire breakage. could be.

Further, in the present embodiment, as shown in FIG. 10, when the control unit 21 acquires the positive peak waveform 204 and the negative peak waveform 204 with similarity higher than a predetermined value, the acquired Based on the number of peak waveforms 204 between the positive peak waveform 204 and the negative peak waveform 204, control is performed to detect the type of damage to the wire rope 101. FIG. This is because the number of peak waveforms 204 between the positive peak waveforms 204 and the negative peak waveforms 204 tends to differ depending on the type of damage to the wire rope 101 . Specifically, if the number of peak waveforms 204 between the positive and negative peak waveforms 204 is less than a predetermined threshold value (that is, 0 or less), the type of damage to the wire rope 101 is wire breakage. Or it could be a kink. Also, if the number of peak waveforms 204 between the positive and negative peak waveforms 204 is equal to or greater than a predetermined threshold value (that is, many), there is a possibility that the type of damage to wire rope 101 is hail. Although the predetermined threshold value is not particularly limited, it can be set to 2, for example. This is because the number of peak waveforms 204 between the positive and negative peak waveforms 204 is about 0 or 1 in many cases when the type of damage to the wire rope 101 is wire breakage or kink.

<Detection of type of wire rope damage based on parameters>
In addition, in the present embodiment, as shown in FIG. 11, the control unit 21 acquires a parameter 207 specifying the peak waveform 204 based on the peak waveform 204, and determines the wire rope 101 based on the acquired parameter 207. Control is performed to detect the type of damage.

Specifically, based on the width 207 a of the peak waveform 204 , the sharpness 207 b of the peak waveform 204 , and the slope 207 c of the baseline 203 of the peak waveform 204 as the parameters 207 , the control unit 21 detects damage to the wire rope 101 . Control to detect the type of Width 207a of peak waveform 204 can be, for example, the length of baseline 203 of peak waveform 204 . That is, the width 207a of the peak waveform 204 can be, for example, the length between the intersections 202a of the waveforms of the measured data 201 and the smoothed data 202, which are adjacent to each other. The peak 207b of the peak waveform 204 can be, for example, the height 207d of the peak waveform 204 relative to the width 207a of the peak waveform 204. FIG. Note that the height 207d of the peak waveform 204 can be, for example, the length from the baseline 203 to the peak top. The slope 207c of the baseline 203 of the peak waveform 204 can be, for example, the angle formed by the line along the time axis of the measurement data 201 and the baseline 203 .

As shown in FIG. 12, the width 207a of the peak waveform 204 tends to vary depending on the type of damage to the wire rope 101 . Specifically, when the width 207a of the peak waveform 204 is large, there is a possibility that the type of damage to the wire rope 101 is seams. Moreover, when the width 207a of the peak waveform 204 is small, the type of damage to the wire rope 101 may be wire breakage or kink. The size of the width 207a of the peak waveform 204 can be determined by setting a threshold value for the width 207a, for example. The threshold for width 207a can be set, for example, based on the width of reference peak waveform 205 (205a-c).

Moreover, the sharpness 207b of the peak waveform 204 tends to differ depending on the type of damage to the wire rope 101 . Specifically, when the sharpness 207b of the peak waveform 204 is large, there is a possibility that the type of damage to the wire rope 101 is wire breakage or kink. Moreover, when the sharpness 207b of the peak waveform 204 is small, there is a possibility that the type of damage to the wire rope 101 is seams. The magnitude of sharpness 207b of peak waveform 204 can be determined using, for example, a threshold value for sharpness 207b. The threshold for cusps 207b can be set, for example, based on the cusps of the reference peak waveform 205 (205a-c).

Moreover, the slope 207c of the baseline 203 of the peak waveform 204 tends to differ depending on the type of damage to the wire rope 101 . Specifically, when the slope 207c of the baseline 203 of the peak waveform 204 is large, there is a possibility that the type of damage to the wire rope 101 is seams. Also, when the slope 207c of the baseline 203 of the peak waveform 204 is small, the type of damage to the wire rope 101 may be wire breakage or kink. The magnitude of the slope 207c of the baseline 203 of the peak waveform 204 can be determined using, for example, a threshold value for the slope 207c. The threshold for slope 207c can be set, for example, based on the slope of baseline 203 of reference peak waveform 205 (205a-c).

<Detection of types of wire rope damage based on similarity and parameters>
As shown in FIG. 13, based on the similarity 206 and the parameter 207, the control unit 21 sets the evaluation value, which is a value indicating the possibility that the damage is the damage, for each of the wire breakage, the kink, and the crack. is acquired, and control is performed to detect the type of damage to the wire rope 101 based on the acquired evaluation value.

Specifically, first, the control unit 21 determines the evaluation value of the magnitude of the similarity 206 and the order of appearance of the positive and negative peak waveforms 204 for each of wire breakage, kink, and seam, according to a predetermined evaluation procedure. Evaluation value, evaluation value of number of peak waveforms 204 between positive and negative peak waveforms 204, evaluation value of width 207a of peak waveform 204, evaluation value of sharpness 207b of peak waveform 204, and baseline 203 of peak waveform 204 Control is performed to acquire the evaluation value of the slope 207c. Then, the control unit 21 acquires the total value of the plurality of evaluation values for each of the wire breakage, the kink, and the crack, and determines the damage having the highest total value among the acquired three total values. Control is performed to detect the type of damage 101 . Further, the control unit 21 controls transmission of the detection result of the type of damage to the wire rope 101 to the external device 300 .

Then, the control unit 302 of the external device 300 controls the display unit 303 to display the received detection result of the type of damage to the wire rope 101 . As a result, an inspector using the wire rope inspection system 100 can confirm whether the damage to the wire rope 101 is wire breakage, kink, or crack. As a result, the inspector can perform maintenance work according to the type of damage to the wire rope 101 . That is, if the damage to the wire rope 101 is wire breakage, the inspector determines that urgent action is required, or if the damage to the wire rope 101 is a kink, no immediate action is required, but monitoring is required. or if the wire rope 101 is damaged, it can be determined that observation is necessary.

(Measurement data processing system)
Next, the data processing system of the wire rope inspection system 100 will be described with reference to FIGS. 14 and 15(A) and (B).

As shown in FIG. 14 , the wire rope inspection device 200 is configured to be able to detect the type of damage to the wire rope 101 while acquiring measurement data 201 using the detection coil 10 . That is, the wire rope inspection device 200 is configured to be able to detect the type of damage to the wire rope 101 while processing the measurement data 201 in real time.

Specifically, the wire rope inspection device 200 further includes an input controller 27 , a first memory 28 a , a second memory 28 b and a memory switcher 29 . The input controller 27 receives measurement data 201 from the sensing coil 10 and transmits it to the first memory 28a or the second memory 28b. First memory 28 a and second memory 28 b store measurement data 201 received from input controller 27 . The memory switcher 29 receives the measurement data 201 from the first memory 28 a or the second memory 28 b and transmits it to the control section 21 . Based on the measurement data 201 received from the memory switcher 29, the control unit 21 performs the damage detection process of the wire rope 101 described above.

As shown in FIGS. 15A and 15B, wire rope inspection apparatus 200 stores measurement data 201 in either first memory 28a or second memory 28b, and The measurement data 201 stored in the memory 28b which is not storing the measurement data 201 is transmitted to the control unit 21, and the type of damage of the wire rope 101 is detected.

Specifically, as shown in FIG. 15A, when storing the measurement data 201 in the first memory 28a, the input controller 27 stores the measurement data 201 received from the sensing coil 10 in the first memory 28a. Switch the data path to transmit. At this time, the memory switcher 29 switches the data path so as to connect the second memory 28b and the controller 21 . Thereby, the measurement data 201 stored in the second memory 28 b is transmitted to the control section 21 . Then, when a predetermined amount of measurement data 201 is stored in the first memory 28a, the input controller 27 transmits the measurement data 201 received from the sensing coil 10 to the second memory 28b. The data path is switched. At this time, the data path is switched by the memory switcher 29 so that the first memory 28a and the control unit 21 are connected.

Further, as shown in FIG. 15(B), when storing the measurement data 201 in the second memory 28b, the input controller 27 causes the measurement data 201 received from the sensing coil 10 to be transmitted to the second memory 28b. switch the data path to At this time, the memory switcher 29 switches the data path so as to connect the first memory 28 a and the controller 21 . Thereby, the measurement data 201 stored in the first memory 28 a is transmitted to the control section 21 . Then, when a predetermined amount of measurement data 201 is stored in the second memory 28b, the input controller 27 transmits the measurement data 201 received from the sensing coil 10 to the first memory 28a. The data path is switched. At this time, the data path is switched by the memory switcher 29 so that the second memory 28b and the control unit 21 are connected. Thus, the first memory 28a and the second memory 28b do not transmit the measurement data 201 to the control section 21 while the measurement data 201 from the sensing coil 10 is being stored.

As a result, the control unit 21 can sequentially receive the measurement data 201 stored in the first memory 28a or the second memory 28b and sequentially perform the process of detecting the type of damage to the wire rope 101. FIG. In addition, the control unit 21 performs control to sequentially transmit detection of types of damage to the wire rope 101 to the external device 300 . Then, the control unit 302 of the external device 300 controls the display unit 303 to sequentially display the received detection results of the type of damage to the wire rope 101 .

(Effect of this embodiment)
The following effects can be obtained in this embodiment.

In this embodiment, as described above, the peak waveform 204 is obtained from the measurement data 201 based on the baseline 203 and the type of damage to the wire rope 101 is detected based on the peak waveform 204 . As a result, not only the presence or absence of damage to the wire rope 101 but also the type of damage to the wire rope 101 can be detected and notified to the inspector. As a result, it is not necessary for an inspector to check the measurement data 201 to determine the type of damage to the wire rope 101. Therefore, by detecting the type of damage to the wire rope 101, maintenance work for the wire rope 101 can be supported. can be done effectively. Further, as described above, by obtaining the peak waveform 204 from the measurement data 201 based on the baseline 203, unlike the case where the peak waveform 204 is obtained without being based on the baseline 203, the wire rope 101 An accurate peak waveform 204 with reduced low-frequency components due to deformation of the wire rope 101 caused by damage can be obtained. As a result, the type of damage to wire rope 101 can be easily detected based on accurate peak waveform 204 in which low-frequency components due to deformation of wire rope 101 caused by damage to wire rope 101 are reduced.

Further, in the present embodiment, as described above, the control unit 21 controls the measurement value group having a positive value with respect to the baseline 203 and the measurement value group having a negative value with respect to the baseline 203. is configured to perform control to acquire as the peak waveform 204 . As a result, both the accurate positive peak waveform 204 and the negative peak waveform 204 in which the low-frequency components due to deformation of the wire rope 101 caused by damage to the wire rope 101 are reduced can be obtained. As a result, based on both the accurate positive peak waveform 204 and the negative peak waveform 204 in which the low frequency components due to the deformation of the wire rope 101 caused by the damage of the wire rope 101 are reduced, the damage of the wire rope 101 can be detected. Kind can be detected more easily.

Moreover, in this embodiment, as described above, the wire rope inspection system 100 is configured to include the storage unit 23 in which the reference peak waveform 205 is stored. Also, the control unit 21 is configured to perform control for detecting the type of damage to the wire rope 101 based on the comparison result between the peak waveform 204 and the reference peak waveform 205 . As a result, the type of damage to the wire rope 101 can be detected based on the comparison result between the peak waveform 204 and the reference peak waveform 205 that clearly shows the characteristics of the damage. can be detected.

Further, in this embodiment, as described above, the reference peak waveform 205 is obtained based on the known data, which is the measurement data 201 in which the type of damage to the wire rope 101 is known, and the smoothed data of the known data is obtained. Based on the obtained smoothed data of the known data, a baseline of the known data is obtained, and based on the obtained baseline of the known data, a peak waveform obtained from the known data is constructed. As a result, the peak waveform 204 can be compared with the reference peak waveform 205 obtained by the same processing as that for obtaining the peak waveform 204, so that the peak waveform 204 and the reference peak waveform 205 can be easily compared. can do.

Further, in the present embodiment, as described above, the control unit 21 acquires the similarity 206 between the peak waveform 204 and the reference peak waveform 205 as a comparison result between the peak waveform 204 and the reference peak waveform 205. In addition, based on the acquired similarity 206, it is configured to perform control to detect the type of damage to the wire rope 101. FIG. As a result, the type of damage to the wire rope 101 can be detected based on the degree of similarity 206 that indicates a good correlation between the peak waveform 204 and the reference peak waveform 205. Therefore, the type of damage to the wire rope 101 can be detected. can be detected more accurately.

Further, in the present embodiment, as described above, the control unit 21 divides the peak waveform 204 by a predetermined number n, and obtains the predetermined number n of representative values P1 to Pn. , Based on the representative values P1 to Pn for a predetermined number n of the acquired peak waveform 204 and the representative values SP1 to SPn for a predetermined number n of the reference peak waveform 205, a similarity 206 is acquired. configured to control As a result, the similarity 206 between the peak waveform 204 and the reference peak waveform 205 can be acquired in a state in which the peak waveform 204 is compressed to a predetermined number n of representative values P1 to Pn. 206 can be reduced.

Further, in the present embodiment, as described above, when the control unit 21 acquires the positive peak waveform 204 and the negative peak waveform 204 with similarity 206 higher than the predetermined value, the acquired positive peak waveform 204 Based on the order of appearance of the peak waveform 204 and the negative peak waveform 204, control is performed to detect the type of damage to the wire rope 101. As a result, the type of damage to wire rope 101 can be easily detected by utilizing the fact that the appearance order of positive peak waveform 204 and negative peak waveform 204 differs depending on the type of damage to wire rope 101 .

Further, in the present embodiment, as described above, when the control unit 21 acquires the positive peak waveform 204 and the negative peak waveform 204 with similarity 206 higher than the predetermined value, the acquired positive peak waveform 204 Based on the number of peak waveforms 204 between the peak waveform 204 and the negative peak waveform 204, control is performed to detect the type of damage to the wire rope 101. As a result, the type of damage to the wire rope 101 can be easily detected by utilizing the difference in the number of peak waveforms 204 between the positive peak waveforms 204 and the negative peak waveforms 204 depending on the type of damage to the wire rope 101. can do.

Further, in the present embodiment, as described above, the control unit 21 acquires the parameter 207 that specifies the peak waveform 204 based on the peak waveform 204, and based on the acquired parameter 207, measures the damage of the wire rope 101. configured to perform control to detect the type of As a result, the type of damage to the wire rope 101 can be detected based on the parameter 207 that indicates the shape of the peak waveform 204. Therefore, the fact that the shape of the peak waveform 204 differs depending on the type of damage to the wire rope 101 is utilized. By doing so, the type of damage to the wire rope 101 can be accurately detected.

Further, in the present embodiment, as described above, the control unit 21 is controlled based on the width 207a of the peak waveform 204, the sharpness 207b of the peak waveform 204, and the slope 207c of the baseline 203 of the peak waveform 204 as the parameters 207. and control to detect the type of damage to the wire rope 101 is performed. As a result, the width 207a of the peak waveform 204, the sharpness 207b of the peak waveform 204, and the inclination 207c of the baseline 203 of the peak waveform 204 differ depending on the type of damage to the wire rope 101. The type of damage can be easily and accurately detected.

Further, in this embodiment, as described above, the control unit 21 detects, as types of damage to the wire rope 101, wire breakage, fixed deformation (kink) due to external pressure, and loosening of the twist of the wire. configured to control As a result, it is possible to detect wire breakage, fixed deformation (kink) due to external pressure, and loosening of the wire strands, which are damages that are likely to occur in the wire rope 101. Kind detection can be done effectively.

[Modification]
It should be noted that the embodiments disclosed this time should be considered as examples and not restrictive in all respects. The scope of the present invention is indicated by the scope of the claims rather than the above-described description of the embodiments, and includes all modifications (modifications) within the meaning and scope equivalent to the scope of the claims.

For example, in the above embodiments, an example in which wire ropes are used in elevators has been shown, but the present invention is not limited to this. In the present invention, wire ropes may be used in configurations other than elevators, such as cranes, suspension bridges and robots.

Further, in the above embodiment, the wire rope inspection device of the wire rope inspection system has shown an example in which the type of wire rope damage is detected and controlled, but the present invention is not limited to this. In the present invention, an external device of the wire rope inspection system may detect and control the type of wire rope damage. In this case, for example, the control unit of the external device acquires the smoothed data of the measured data based on the measured data acquired by the detection coil, and acquires the baseline of the measured data based on the acquired smoothed data. Then, based on the obtained baseline, a peak waveform is obtained from the measurement data, and control is performed to detect the type of damage to the wire rope based on the obtained peak waveform.

Also, in the above embodiment, the detector coil is a differential coil having a pair of receiver coils, but the present invention is not limited to this. In the present invention, the sensing coil may consist of a single coil.

Further, in the above-described embodiment, an example is shown in which three types of damage to the wire rope are detected: wire breakage, fixed deformation (kink) due to external pressure, and loosening of the twist of the wire (crotch). The present invention is not limited to this. In the present invention, any one or two of wire breakage, fixed deformation (kink) due to external pressure, and loosening of wire strands may be detected as types of wire rope damage. Further, as the types of wire rope damage, damage other than wire breakage, fixed deformation (kink) due to external pressure, and looseness of twist of the wire may be detected.

Further, in the above embodiment, an example is shown in which an evaluation value is acquired based on both the similarity and the parameter, and the type of wire rope damage is detected based on the acquired evaluation value. The present invention is not limited to this. In the present invention, an evaluation value may be obtained based on only one of the degree of similarity and the parameter, and the type of damage to the wire rope may be detected based on the obtained evaluation value. Moreover, in the present invention, it is not always necessary to obtain an evaluation value in order to detect the type of damage to the wire rope. That is, the type of wire rope damage may be detected based on at least one of the degree of similarity and the parameter without obtaining an evaluation value.

Further, in the above-described embodiment, an example in which the peak waveform is divided by a predetermined number when the degree of similarity is acquired has been described, but the present invention is not limited to this. In the present invention, the peak waveform does not necessarily have to be divided by a predetermined number when the similarity is obtained. That is, the similarity between the peak waveform and the reference peak waveform may be obtained without dividing the peak waveform by a predetermined number.

Further, in the above embodiment, when the type of wire rope damage is detected based on the similarity, the magnitude of the similarity, the appearance order of the high similarity positive peak waveform and the negative peak waveform, and Although an example in which the type of wire rope damage is detected based on the number of peak waveforms between a positive peak waveform and a negative peak waveform with high similarity has been shown, the present invention is not limited to this. In the present invention, when the type of wire rope damage is detected based on the similarity, the magnitude of the similarity, the appearance order of the high similarity positive peak waveform and the negative peak waveform, and the high similarity The type of wire rope damage may be detected based on any one or two of the number of peak waveforms between the positive peak waveform and the negative peak waveform of . Also, when the type of wire rope damage is detected based on the similarity, the magnitude of the similarity, the appearance order of the positive peak waveform and the negative peak waveform of the high similarity, and the positive peak waveform of the high similarity. The type of wire rope damage may be detected based on other than the number of peak waveforms between the peak waveform of and the negative peak waveform.

Further, in the above embodiment, when the type of damage to the wire rope is detected based on the parameters, the width of the peak waveform, the sharpness of the peak waveform, and the slope of the baseline of the peak waveform are used to detect the damage to the wire rope. Although an example in which the type of damage is detected has been shown, the present invention is not limited to this. In the present invention, when the type of wire rope damage is detected based on parameters, any one or two of the width of the peak waveform, the sharpness of the peak waveform, and the slope of the baseline of the peak waveform , the type of wire rope damage may be detected. Also, when the type of damage to the wire rope is detected based on the parameters, the type of damage to the wire rope is determined based on factors other than the width of the peak waveform, the sharpness of the peak waveform, and the slope of the baseline of the peak waveform. may be detected.

[Aspect]
It will be appreciated by those skilled in the art that the exemplary embodiments described above are specific examples of the following aspects.

(Item 1)
a detection coil for detecting changes in the magnetic field of the wire rope;
A control unit that performs control to detect the type of damage to the wire rope,
The control unit obtains smoothed data obtained by smoothing the measured data based on the measured data obtained by the detection coil, and converts the measured data based on the obtained smoothed data. Control is performed to acquire a baseline, acquire a peak waveform from the measurement data based on the acquired baseline, and detect the type of damage to the wire rope based on the acquired peak waveform. A wire rope inspection system configured to:

(Item 2)
The control unit controls to acquire a measured value group having a positive value with respect to the baseline and a measured value group having a negative value with respect to the baseline as the peak waveform. The wire rope inspection system according to item 1, wherein the wire rope inspection system is configured to:

(Item 3)
further comprising a storage unit in which the reference peak waveform is stored;
The wire according to item 1 or 2, wherein the control unit is configured to perform control to detect a type of damage to the wire rope based on a comparison result between the peak waveform and the reference peak waveform. Rope inspection system.

(Item 4)
The reference peak waveform is obtained by obtaining smoothed data, which is data obtained by smoothing the known data, based on known data, which is measurement data in which the type of damage to the wire rope is known. Item 3, wherein a baseline of the known data is obtained based on data smoothed data, and a peak waveform obtained from the known data based on the obtained baseline of the known data. Wire rope inspection system.

(Item 5)
The control unit obtains a degree of similarity between the peak waveform and the reference peak waveform as a comparison result between the peak waveform and the reference peak waveform, and based on the obtained degree of similarity, the 5. A wire rope inspection system according to item 3 or 4, configured to perform control to detect the type of wire rope damage.

(Item 6)
The control unit divides the peak waveform by a predetermined number, acquires the predetermined number of representative values, and obtains the predetermined number of representative values of the acquired peak waveform. 6. The wire rope inspection system according to item 5, wherein control is performed to acquire the degree of similarity based on a predetermined number of representative values of the reference peak waveform.

(Item 7)
When the control unit acquires the positive peak waveform and the negative peak waveform with a similarity higher than a predetermined value, the appearance of the acquired positive peak waveform and the negative peak waveform 7. The wire rope inspection system according to any one of items 4 to 6, configured to perform control for detecting the type of damage to the wire rope based on the order.

(Item 8)
When the control unit acquires the positive peak waveform and the negative peak waveform with a high similarity higher than a predetermined value, the control unit performs 8. The wire rope inspection system according to any one of items 4 to 7, which is configured to perform control to detect the type of damage to the wire rope based on the number of peak waveforms of.

(Item 9)
The control unit is configured to acquire a parameter specifying the peak waveform based on the peak waveform and to perform control to detect a type of damage to the wire rope based on the acquired parameter. The wire rope inspection system according to any one of items 1 to 8.

(Item 10)
The control unit controls the damage of the wire rope based on at least one of the width of the peak waveform, the sharpness of the peak waveform, and the slope of the baseline of the peak waveform as the parameter. Item 10. The wire rope inspection system according to item 9, which is configured to perform control to detect the type of.

(Item 11)
The control unit is configured to perform control to detect at least one of wire breakage, fixed deformation due to external pressure, and loose twist of the wire rope as the type of damage to the wire rope. , the wire rope inspection system according to any one of items 1 to 10.

(Item 12)
detecting changes in the magnetic field of the wire rope;
obtaining smoothed data obtained by smoothing the measured data based on the measured data obtained by detecting changes in the magnetic field of the wire rope;
obtaining a baseline of the measured data based on the smoothed data;
obtaining a peak waveform from the measured data based on the baseline;
and detecting a type of damage to the wire rope based on the peak waveform.

10 detection coil 21 control unit 23 storage unit 100 wire rope inspection system 101 wire rope 201 measurement data 202 smoothed data 203 baseline 204 peak waveform 205, 205a-c reference peak waveform 206 similarity 207 parameter 207a width of peak waveform 207b peak Sharpness of waveform 207c Slope of baseline of peak waveform n Predetermined number P1 to Pn Representative values of a predetermined number of peak waveforms SP1 to SPn Representative values of a predetermined number of reference peak waveforms

Claims (12)

a detection coil for detecting changes in the magnetic field of the wire rope;
A control unit that performs control to detect the type of damage to the wire rope,
The control unit obtains smoothed data obtained by smoothing the measured data based on the measured data obtained by the detection coil, and converts the measured data based on the obtained smoothed data. Control is performed to acquire a baseline, acquire a peak waveform from the measurement data based on the acquired baseline, and detect the type of damage to the wire rope based on the acquired peak waveform. A wire rope inspection system configured to: The control unit controls to acquire a measured value group having a positive value with respect to the baseline and a measured value group having a negative value with respect to the baseline as the peak waveform. 2. The wire rope inspection system of claim 1, wherein the wire rope inspection system comprises: further comprising a storage unit in which the reference peak waveform is stored;
2. The wire rope according to claim 1, wherein the control section is configured to perform control to detect a type of damage to the wire rope based on a comparison result between the peak waveform and the reference peak waveform. inspection system. The reference peak waveform is obtained by obtaining smoothed data, which is data obtained by smoothing the known data, based on known data, which is measurement data in which the type of damage to the wire rope is known. 4. The peak waveform obtained from the known data based on the obtained baseline of the known data obtained based on the smoothed data of the data, according to claim 3. wire rope inspection system. The control unit obtains a degree of similarity between the peak waveform and the reference peak waveform as a comparison result between the peak waveform and the reference peak waveform, and based on the obtained degree of similarity, the 4. The wire rope inspection system according to claim 3, configured to perform control to detect the type of wire rope damage. The control unit divides the peak waveform by a predetermined number, acquires the predetermined number of representative values, and obtains the predetermined number of representative values of the acquired peak waveform. 6. The wire rope inspection system according to claim 5, configured to control acquisition of said degree of similarity based on a predetermined number of representative values of said reference peak waveform. When the control unit acquires the positive peak waveform and the negative peak waveform with a similarity higher than a predetermined value, the appearance of the acquired positive peak waveform and the negative peak waveform 6. The wire rope inspection system according to claim 5 , configured to perform control for detecting the type of damage to the wire rope based on the order. When the control unit acquires the positive peak waveform and the negative peak waveform with a high similarity higher than a predetermined value, the control unit performs 6. The wire rope inspection system according to claim 5 , configured to perform control for detecting the type of damage to said wire rope based on the number of said peak waveforms of . The control unit is configured to acquire a parameter specifying the peak waveform based on the peak waveform, and to perform control to detect a type of damage to the wire rope based on the acquired parameter. 2. The wire rope inspection system of claim 1, wherein: The control unit controls the damage of the wire rope based on at least one of the width of the peak waveform, the sharpness of the peak waveform, and the slope of the baseline of the peak waveform as the parameter. 10. The wire rope inspection system according to claim 9, configured to perform control to detect the type of wire rope. The control unit is configured to perform control to detect at least one of wire breakage, fixed deformation due to external pressure, and loose twist of the wire rope as the type of damage to the wire rope. A wire rope inspection system according to claim 1. detecting changes in the magnetic field of the wire rope;
obtaining smoothed data obtained by smoothing the measured data based on the measured data obtained by detecting changes in the magnetic field of the wire rope;
obtaining a baseline of the measured data based on the smoothed data;
obtaining a peak waveform from the measured data based on the baseline;
and detecting a type of damage to the wire rope based on the peak waveform.

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