JP7276233B2 - Elevator wire rope inspection device, elevator wire rope inspection system, and elevator wire rope inspection method - Google Patents

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an elevator wire rope inspection device, an elevator wire rope inspection system, and an elevator wire rope inspection method, and more particularly to an elevator wire rope that detects the state of the wire rope based on changes in the magnetic field of the wire rope. The present invention relates to a wire rope inspection device, an elevator wire rope inspection system, and an elevator wire rope inspection method.

Conventionally, an elevator wire rope inspection device, an elevator wire rope inspection system, and an elevator wire rope inspection method for detecting the state of a wire rope based on changes in the magnetic field of the elevator wire rope are known (for example, See Patent Document 1).

The wire rope inspection device of Patent Document 1 is configured to inspect the wire rope while moving relative to the wire rope. Specifically, the wire rope inspection device of Patent Document 1 includes a first detection signal obtained by a differential coil in a first measurement of the wire rope, and a differential coil in a second measurement after the first measurement. The state of the wire rope is detected based on the difference at substantially the same position as the second detection signal. As a result, the magnetic characteristics (noise data) unique to the wire rope are removed (cancelled), and the signal caused by the wire rope damage or the like is extracted.

In addition, the relative movement speed and relative acceleration with respect to the wire rope of the wire rope inspection device of Patent Document 1 are measured at the start of movement of the cage of the elevator, at the end of movement (at the time of stop), and during the movement of the cage. different from each other at times. Therefore, the wire rope inspection device moves from the starting point on one side of the predetermined section of the wire rope (i.e., the starting point outside the predetermined section) to the end point on the other side of the predetermined section (i.e., outside the predetermined section). and the detection signal corresponding to the predetermined section obtained when the wire rope inspection device moves relatively to the end point of the wire rope from one end (start point) of the predetermined section to the other of the predetermined section A detection signal obtained when the object has relatively moved to the end (end point) has a different waveform shape even if the detection signal corresponds to the same section. Therefore, in order to reliably remove (cancel) the inherent magnetic characteristics (noise data) by calculating the difference between the first detection signal and the second detection signal, in the first measurement and the second measurement, It is necessary to align the start and end points of the wire rope to be measured by the wire rope inspection device.

WO2019/150539

However, in the wire rope inspection device described in Patent Document 1, when the positions of the starting point and the end point of the wire rope to be measured by the wire rope inspection device are not aligned between the first measurement and the second measurement, , it may not be possible to reliably remove (cancel) the inherent magnetic properties (noise data) of the wire rope. For this reason, if the wire rope inspection device moves relative to an arbitrary portion of the wire rope due to the movement of the cage of the elevator in an arbitrary movement section, the wire rope inspection may not be performed accurately. There is Therefore, an elevator wire rope inspection device, an elevator wire rope inspection system, and an elevator wire rope inspection method capable of accurately inspecting a wire rope even when the car portion of the elevator moves in an arbitrary movement section. is desired.

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 accurately inspect a wire rope even when the cage of an elevator moves in an arbitrary moving section. An object of the present invention is to provide an elevator wire rope inspection device, an elevator wire rope inspection system, and an elevator wire rope inspection method capable of performing the inspection.

In order to achieve the above object, an elevator wire rope inspection apparatus in a first aspect of the present invention includes a detection coil for detecting changes in the magnetic field of a plurality of elevator wire ropes for raising and lowering a car of the elevator; a control unit that receives a detection signal of the wire rope acquired by the coil, wherein the control unit is detected by the detection coil based on movement of the cage through one movement section of the plurality of movement sections. and a reference signal corresponding to one movement section among a plurality of reference signals detected when the cage moves in each of a plurality of movement sections stored in advance. Based on this, it is configured to detect the state of the wire rope.

An elevator wire rope inspection system according to a second aspect of the present invention includes an elevator wire rope inspection device including a detection coil for detecting changes in the magnetic field of a plurality of elevator wire ropes for raising and lowering a car of the elevator; a control device that receives a detection signal of the wire rope acquired by the coil, wherein the control device is detected by the detection coil based on movement of the cage through one movement section of the plurality of movement sections. and a reference signal corresponding to one movement section among a plurality of reference signals detected when the cage moves in each of a plurality of movement sections stored in advance. Based on this, it is configured to detect the state of the wire rope.

An elevator wire rope inspection method according to a third aspect of the present invention is characterized in that a detection coil for detecting changes in a magnetic field of a plurality of elevator wire ropes for raising and lowering a car of an elevator detects a change in the magnetic field of the car in a plurality of moving sections. A step of acquiring a detection signal when moving in one movement section, a detection signal detected by the detection coil, and a signal detected when the pre-stored car portion moves in each of the plurality of movement sections and detecting the state of the wire rope based on a difference from a reference signal corresponding to one moving section, among a plurality of reference signals.

In the elevator wire rope inspection device in the first aspect, the elevator wire rope inspection system in the second aspect, and the elevator wire rope inspection method in the third aspect, as described above, one movement The state of the wire rope is detected based on the difference between the detection signal detected by the detection coil based on the movement of the section and the pre-stored reference signal corresponding to one movement section. As a result, the reference signal corresponding to each of a plurality of movement sections in which the car moves is stored (prepared) in advance, so that the detection signal detected when the car of the elevator moves in one movement section and the , and a pre-stored reference signal corresponding to one movement segment, the state of the wire rope can be detected. As a result, the start point and the end point of the wire rope to be inspected by the elevator wire rope inspection device can be aligned in the detection signal and the reference signal for obtaining the difference. As a result, the wire rope can be accurately inspected even when the car of the elevator moves in an arbitrary movement section.

It is a figure showing composition of a wire rope inspection device by a 1st embodiment. BRIEF DESCRIPTION OF THE DRAWINGS It is the figure which showed the hoistway and elevator in which the wire rope inspection apparatus by 1st Embodiment is provided. Fig. 2 is a block diagram showing a control configuration of the wire rope inspection device according to the first embodiment; FIG. 3 is a diagram for explaining the configurations of a magnetic field application section and a detection section of the wire rope inspection device according to the first embodiment; FIG. 4 is a diagram for explaining a difference between a detection signal and a reference signal when the wire rope according to the first embodiment is not damaged; FIG. 4 is a diagram for explaining a difference between a detection signal and a reference signal when the wire rope is damaged according to the first embodiment; 1 shows a building in which an elevator according to the first embodiment is installed; FIG. Fig. 3 shows a reference signal stored in the server according to the first embodiment; FIG. 4 is a diagram for explaining a method of selecting a reference signal corresponding to a detection signal according to the first embodiment; FIG. FIG. 4 is a flowchart showing control related to state detection of the wire rope according to the first embodiment; FIG. 10 is a diagram for explaining a method of selecting a reference signal corresponding to a detection signal according to the second embodiment; FIG. FIG. 9 is a flow diagram showing control related to state detection of a wire rope according to the second embodiment; FIG. 4 is a diagram showing the configuration of a wire rope inspection system according to a modification of the first and second embodiments;

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

[First embodiment]
The configuration of a wire rope inspection device 100 according to the first embodiment will be described with reference to FIGS. 1 to 10. FIG.

(Configuration of wire rope inspection device)
As shown in FIG. 1, a wire rope inspection device 100 is configured to inspect a wire rope W, which is an object to be inspected. The wire rope W is an elevator wire rope that raises and lowers the car portion E1 (see FIG. 2) of the elevator E (see FIG. 2). The wire rope inspection device 100 is configured to inspect the wire rope W for damage. The wire rope inspection device 100 is an example of the "elevator wire rope inspection device" in the claims.

Note that the damage to the wire rope W refers to the detection direction caused by thread, local abrasion, wire breakage, dent, corrosion, crack, break, etc. It is a broad concept that includes changes in cross-sectional area, changes in magnetic permeability caused by rust of the wire rope W, welding burns, contamination of impurities, changes in composition, etc., and other parts where the wire rope W becomes uneven.

A plurality of wire ropes W are provided. Although five wire ropes W are illustrated in FIG. 1 for simplification, there are cases where about ten wire ropes are provided. Here, in the first embodiment, the later-described differential coil 10 of the wire rope inspection device 100 is configured to collectively detect changes in magnetic fields of a plurality of wire ropes W. As shown in FIG. That is, the differential coil 10 acquires one detection signal in which the detection signals of the plurality of wire ropes W are combined. The wire rope inspection device 100 (differential coil 10) is configured to inspect a plurality of wire ropes W in a non-contact state.

As shown in FIG. 2, the wire rope inspection device 100 inspects the wire rope W while being relatively moved along the surface of the wire rope W used in the elevator E. As shown in FIG. The elevator E includes a cage E1 and a hoist E2 that winds up the wire rope W to raise and lower the cage E1. The wire rope inspection device 100 is configured to inspect a moving (wound up) wire rope W while being fixed in the vicinity directly below the hoisting machine E2. The wire rope W is arranged so as to extend in the X direction at the position of the wire rope inspection device 100 . It should be noted that the basket E1 moves at a higher moving speed during the midway movement than at the start and end of the movement (stopping). Further, the movement speed of the basket portion E1 at the start of movement and the movement speed of the basket portion E1 at the end of movement (when stopped) may be different from each other, or may be the same.

Also, the car E1 of the elevator E ascends and descends the hoistway 101 . The hoisting machine E2 is provided in the hoistway 101 of the elevator E. As shown in FIG. That is, the elevator E is a so-called machine room-less type elevator. Note that the elevator E may be of a type with a machine room (a type in which the hoisting machine E2 is provided in a machine room isolated from the hoistway 101). Also, in the first embodiment, the elevator E is assumed to be installed in the five-story building 102 . Note that the building 102 is not limited to five stories as long as it is two stories or more.

As shown in FIG. 3 , the wire rope inspection device 100 includes a detection section 1 and an electronic circuit section 2 . The detector 1 includes a differential coil 10 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 storage unit 23 stores control programs and the like used for controlling the control unit 21 . Note that the storage unit 23 can be configured by an HDD, an SSD, or the like. The wire rope inspection device 100 also includes a magnetic field application unit 4 (see FIG. 4). The differential coil 10 is an example of the "detection coil" in the claims.

An external device 900 (see FIG. 1) is also connected to the wire rope inspection device 100 via the communication unit 26 .

As shown in FIG. 1 , the external device 900 includes a communication section 901 , an analysis section 902 and a display section 903 . The external device 900 is configured to receive measurement data of the wire rope W by the wire rope inspection device 100 via the communication unit 901 . Further, the external device 900 is configured to analyze the type of damage, such as wire breakage and cross-sectional area change, by the analysis unit 902 based on the received measurement data of the wire rope W. FIG. The external device 900 is also configured to display the analysis result on the display unit 903 . Further, the external device 900 is configured to perform abnormality determination based on the analysis result and display the result on the display unit 903 .

As shown in FIG. 4 , the wire rope inspection device 100 is configured to detect changes in the magnetic field (magnetic flux) of the wire rope W using the differential coil 10 . The wire rope inspection device 100 is configured so that no DC magnetizer is arranged near the coil.

It should be noted that the change in the magnetic field refers to the temporal change in the strength of the magnetic field detected by the detection unit 1 due to the relative movement of the wire rope W and the detection unit 1, and the change in the magnetic field applied to the wire rope W over time. This is a broad concept that includes temporal changes in the strength of the magnetic field detected by the detector 1 due to changes.

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

The magnetic field applying unit 4 (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 W and in the Y2 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)
As shown in FIG. 4 , the wire rope W passes through the excitation coil 13 . Also, the differential coil 10 is provided inside the excitation coil 13 . Note that the arrangement of the differential coils 10 and the excitation coils 13 is not limited to this. The receiving coil 11 of the differential coil 10 is arranged on the X1 direction side. Also, the receiving coil 12 of the differential 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 W. As shown in FIG. 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.

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

If the wire rope W 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 W is reduced at the defective portion (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, so that the voltage detected by the differential coil 10 changes. The absolute value of the difference (differential signal) increases. On the other hand, the differential signal is substantially zero in a portion without defects (scratches, etc.). Thus, in the differential coil 10, a clear signal (a signal with a good S/N ratio) representing the presence of defects (scratches, etc.) is detected. Thereby, the electronic circuit section 2 can detect the presence of a defect (such as a flaw) in the wire rope W 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 100 . 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 a differential signal (detection signal) of the wire rope W acquired by the differential coil 10 and detect the state of the wire rope W. As shown in FIG. 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 W to the external device 900 via the communication unit 26 . Details of the control unit 21 will be described later.

The reception I/F 22 is configured to receive the differential signal from the differential coil 10 and transmit it to the control section 21 . Specifically, the reception I/F 22 includes an amplifier. Further, the reception I/F 22 is configured to amplify the differential signal of the differential coil 10 and transmit it to the control section 21 .

The excitation I/F 24 is configured to receive a 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 .

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

The wire rope W has inherent magnetic properties. The unique magnetic properties are the magnetic properties that change due to differences in the uniformity of the twist at the cross-sectional position orthogonal to the longitudinal direction (X direction) of the wire rope W, the uniformity of the amount of steel material, etc. It is a characteristic. Here, the degree of uniformity of the twist of the wire rope W and the degree of uniformity of the amount of steel material do not substantially change over time (or are less likely to change significantly over time). Therefore, since the wire rope W has a unique magnetic property, the output at each position in the longitudinal direction (X direction) of the wire rope W for each measurement at different points in time by the wire rope inspection device 100 is Almost the same (measured with good reproducibility).

Specifically, as shown in FIG. 5(A), the reference signal representing the detection signal for each position in the longitudinal direction of the wire rope W obtained by the first measurement by the wire rope inspection device 100 and the reference signal shown in FIG. ), the detection signal representing the signal for each position in the longitudinal direction of the wire rope W obtained by the second measurement performed after the first measurement is substantially the same.

Therefore, when the difference is obtained at substantially the same position in the longitudinal direction (X direction) of the wire rope W, an output waveform with a small amplitude is obtained as shown in FIG. That is, the signals (outputs) based on the magnetic properties unique to the wire rope W at the time of the first measurement and the time of the second measurement are canceled, and a relatively flat output waveform as shown in FIG. 5(C) is obtained. be done. Such results are similar whether the period between the first measurement and the second measurement is relatively short (seconds, minutes) or relatively long (months, years). can get.

Next, a case where the wire rope W is damaged (breakage, etc.) will be described with reference to FIG.

In the detection signal of the second measurement shown in FIG. 6(B), three signals (dotted line portions) caused by the damage of the wire rope W, which do not appear in the reference signal of the first measurement shown in FIG. 6(A), appear. Suppose you are The signal of the part other than the damaged portion in FIG. 6(B) is substantially the same as the reference signal shown in FIG. 6(A).

In this case, in the difference result (see FIG. 6C) between the reference signal in FIG. 6A and the detection signal in FIG. and signals resulting from damage to the wire rope W are not canceled. As a result, comparing the output waveform of FIG. 6C with the output waveform of FIG. It can be seen that the amount is relatively small. That is, the output waveform of FIG. 6(C) is outputted in a manner in which the damaged portion and the undamaged portion of the wire rope can be distinguished more clearly than the output waveform of FIG. 6(B).

Further, as shown in FIG. 8, the server 300 (see FIG. 1) on the network stores the cage E1 (see FIG. 2) in a plurality of inter-floor sections (see FIG. 7) of the building 102 (see FIG. 2). are stored in advance. Specifically, in server 300, reference signals corresponding to each of the plurality of inter-floor sections are individually named and stored. For example, the reference signal stored in the server 300 is given a name such as "reference signal for the inter-floor section from the first floor to the second floor". Further, each of the plurality of reference signals is stored in the server 300 in association with the corresponding inter-floor section information. Note that an inter-floor section means a section from the first floor to another floor (for example, the first floor to the second floor, the second floor to the fifth floor, etc.) of the building 102 . Also, the section between floors is an example of the "moving section" in the scope of claims.

Here, in the first embodiment, the control unit 21 generates a detection signal detected by the differential coil 10 based on the movement of the car E1 through one of the plurality of inter-floor intervals, and The state of the wire rope W is detected based on the difference from the reference signal corresponding to the one inter-floor section among a plurality of reference signals stored in advance in the server 300 . As a specific example, the control section 21 controls the detection signal detected by the differential coil 10 when the car section E1 moves in the inter-floor section from the first floor to the third floor, and the detection signal stored in the server 300. The state of the wire rope W is detected based on the difference between the reference signal and the reference signal corresponding to the inter-floor section from the first floor to the third floor.

In addition, the control unit 21 selects the detection signal detected by the differential coil 10 when the car E1 moves in the inter-floor section from the third floor to the first floor, and the reference signal stored in the server 300, A difference from the reference signal corresponding to the inter-floor section from the third floor to the first floor is calculated. That is, the reference signal corresponding to the inter-floor section from the third floor to the first floor is stored in the server 300 separately from the reference signal corresponding to the inter-floor section from the first floor to the third floor.

Further, the control unit 21 is configured to calculate the difference in a state in which the waveforms are aligned so that the correlation coefficient (correlation function) of the detection signal and the reference signal is maximized. In addition, in order to correct the change in the amplification factor of the amplifier of the magnetic signal over time, the average value or standard deviation of the detection signal is normalized, combined with the reference signal, and then the difference is calculated. good too.

In the first embodiment, the control section 21 detects the detection signal detected by the differential coil 10 based on the movement of the car section E1 in one inter-floor section, and all the reference signals stored in the server 300 in advance. The state of the wire rope W is detected based on the difference from the reference signal corresponding to the one inter-floor section. Specifically, the five-story building 102 has 5×(5−1) (ie, 20) inter-floor sections. The server 300 stores reference signals corresponding to all of the 20 inter-floor sections. In addition, the above calculation is the interval between floors from the n1 floor (n1 is a natural number from 1 to 5) to the n2 floor (n2 is a natural number other than n1 from 1 to 5) and the n2 floor to the n1 floor (the interval during descent) are considered as separate inter-floor intervals for calculation.

Further, the server 300 stores in advance a plurality of reference signals which are signals detected when the car portion E1 moves in each of the plurality of inter-floor sections during the normal operation mode of the elevator E. FIG. That is, the server 300 stores a total of 20 reference signals corresponding to the normal operation mode. In addition, in the normal operation mode, the cage E1 moves at a speed of, for example, 500 m/min.

Further, the server 300 stores in advance a plurality of reference signals which are signals detected when the car portion E1 moves in each of the plurality of inter-floor sections during the inspection operation mode of the elevator. That is, the server 300 stores a total of 20 reference signals corresponding to the inspection operation mode in addition to a total of 20 reference signals corresponding to the normal operation mode. Note that the moving speed of the basket portion E1 in the inspection operation mode is lower than the moving speed of the basket portion E1 in the normal operation mode. Specifically, in the inspection operation mode, the cage E1 moves at a speed of 20 m to 30 m/min, for example.

Here, in the first embodiment, the control unit 21 controls the detection signal detected by the differential coil 10 based on the movement of the car part E1 in one inter-floor section during the normal operation mode of the elevator E, and the The state of the wire rope W is detected based on the difference from the reference signal corresponding to the one floor section among the plurality of reference signals corresponding to the normal operation mode stored in the server 300. ing.

In addition to the detection of the wire rope W in the normal operation mode, the control unit 21 detects by the differential coil 10 based on the movement of the car part E1 in one floor section in the inspection operation mode of the elevator E. The state of the wire rope W is determined based on the difference between the detection signal detected and the reference signal corresponding to the one inter-floor section among the plurality of reference signals corresponding to the inspection operation mode stored in the server 300 in advance. configured to detect

That is, in calculating the difference between the detection signal and the reference signal, the difference between the signals for the same operation mode of the elevator E is calculated, not only for the interval between floors. Thereby, it is possible to obtain the difference between the signals obtained when the moving speeds of the cage E1 are equal to each other.

Further, in the first embodiment, as shown in FIG. 9, the control unit 21 selects the reference signal having the maximum correlation coefficient with the detection signal from among all the reference signals stored in the server 300 in advance. In addition, it is configured to detect the state of the wire rope W based on the difference between the selected reference signal and the detection signal. In the example shown in FIG. 9, correlation coefficients α, β, γ, and δ between the detection signal and each reference signal are calculated. Correlation coefficients are calculated for the number of combinations of detection signals and reference signals, but FIG. 9 shows only four correlation coefficients for simplification. Note that the correlation coefficient between the detection signal and the reference signal means an index representing the degree of similarity between the detection signal and the reference signal.

The control unit 21 selects the reference signal corresponding to the maximum correlation coefficient β among the correlation coefficients α, β, γ, and δ. The control unit 21 is configured to detect the state of the wire rope W based on the difference between the reference signal corresponding to the correlation coefficient β and the detection signal. As a result, it is possible to select the reference signal corresponding to the inter-floor section from which the detection signal was obtained without directly acquiring the information of the inter-floor section to which the car portion E1 of the elevator E has moved.

(Wire rope inspection method)
Next, a method for inspecting the wire rope W will be described with reference to FIG. The inspection method of the wire rope W is an example of the "elevator wire rope inspection method" in the scope of claims.

First, as shown in FIG. 10, in the wire rope W inspection method, a plurality of reference signals, which are signals detected when the cage E1 moves through each of a plurality of inter-floor sections, are stored in the server 300 in advance. A process (step 201) is provided. Specifically, in this step, the server 300 sends a reference signal corresponding to each of all inter-floor sections (20 inter-floor sections) obtained when the elevator E is in the normal operation mode and the inspection operation mode. stored in That is, the server 300 stores 40 kinds of reference signals.

Next, the method for inspecting the wire rope W includes a step (step 202) of acquiring a detection signal by the differential coil 10 when the cage E1 moves in one inter-floor section. Note that this step can be performed both during the normal operation mode of the elevator E and during the inspection operation mode. For example, when the user of the elevator E who got on the car part E1 moves from the first floor to the third floor, a detection signal corresponding to the inter-floor section from the first floor to the third floor is acquired.

The method for inspecting the wire rope W is based on the detection signal corresponding to one inter-floor section detected by the differential coil 10 and the A step of detecting the state of the wire rope W based on the difference from the reference signal corresponding to (step 203). Specifically, the control unit 21 selects the reference signal having the maximum correlation coefficient with the detection signal acquired in step 202 from among all the reference signals. The control unit 21 is configured to calculate the difference between the selected reference signal and the detection signal, and detect the state of the wire rope W based on the calculated difference.

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

(Effect of the wire rope inspection device according to the first embodiment)
The following effects can be obtained with the wire rope inspection device 100 of the first embodiment.

In the first embodiment, as described above, the control unit 21 controls the differential coil 10 (detection coil) and a plurality of reference signals, which are signals detected when the pre-stored car E1 moves through each of the plurality of inter-floor sections. It is configured to detect the state of the wire rope W based on the difference from the corresponding reference signal. As a result, the reference signal corresponding to each of the plurality of inter-floor sections in which the car portion E1 moves is stored (prepared) in advance. The state of the wire rope W can be detected based on the signal and a pre-stored reference signal corresponding to one inter-floor section. As a result, the start point and the end point of the wire rope W to be inspected by the wire rope inspection apparatus 100 can be aligned in the detection signal and the reference signal for obtaining the difference. As a result, the wire rope W can be accurately inspected even when the car portion E1 of the elevator E moves in an arbitrary inter-floor section.

Further, in the first embodiment, as described above, the control unit 21 causes the differential coil 10 (detection coil) to detect movement of the car portion E1 in one inter-floor section (moving section). The state of the wire rope W is detected based on the difference between the detection signal of the wire rope W and the reference signal corresponding to one inter-floor section out of the pre-stored reference signals corresponding to all inter-floor sections. is configured to With this configuration, since reference signals corresponding to all inter-floor sections are stored in advance, the wire rope W can be detected regardless of which inter-floor section the cage E1 moves.

Further, in the first embodiment, as described above, the control unit 21 determines that the car part E1 has moved in one of the plurality of inter-floor intervals (moving intervals) during the normal operation mode of the elevator E. A detection signal detected by the differential coil 10 (detection coil) based on and a signal detected when the car portion E1 moves in each of the plurality of inter-floor sections during the normal operation mode of the elevator E stored in advance. , the state of the wire rope W is detected based on the difference from the reference signal corresponding to one inter-floor section. With this configuration, the wire rope W can be inspected more reliably in the normal operation mode.

Further, in the first embodiment, as described above, in addition to detecting the wire rope W in the normal operation mode, the control unit 21 inspects the elevator E in which the moving speed of the car portion E1 is smaller than that in the normal operation mode. A detection signal detected by the differential coil 10 (detection coil) based on the fact that the car portion E1 has moved in one of a plurality of inter-floor sections (moving sections) during the operation mode, and a pre-stored A reference signal corresponding to one inter-floor section among a plurality of reference signals detected when the car portion E1 moves through each of a plurality of inter-floor sections when the elevator E is in the inspection operation mode. It is configured to detect the state of the wire rope W based on the difference. With this configuration, the wire rope W can be detected not only during the normal operation mode but also during the inspection operation mode. Here, swinging, twisting, and the like of the wire rope W are more likely to occur as the moving speed of the basket portion E1 increases. In addition, the shaking, twisting, and the like may vary even if the operating conditions of the elevator E (moving speed and acceleration of the car portion E1, etc.) are the same. Even if it is removed, noise due to shaking, twisting, etc. may not be canceled (cancelled). Therefore, by detecting the wire rope W in the inspection operation mode in which the moving speed of the basket portion E1 is lower than that in the normal operation mode, the detection signal (reference signal) is less likely to contain the above noise. The wire rope W can be detected more accurately based on the difference from the signal.

Further, in the first embodiment, as described above, the control unit 21 selects the reference signal having the maximum correlation coefficient with the detection signal from among a plurality of reference signals stored in advance, and selects the selected reference signal. It is configured to detect the state of the wire rope W based on the difference between the reference signal and the detection signal. With this configuration, the above information can be obtained only by calculating the correlation coefficient, compared to the case where the information of the inter-floor section (moving section) where the car part E1 has moved is obtained by the position sensor provided in the elevator E. can do. As a result, the number of parts provided in the elevator E can be reduced and the configuration of the elevator E can be simplified by the amount corresponding to the need not to provide the position sensor.

Further, in the first embodiment, as described above, the control unit 21 detects the state of the wire rope W based on the difference between the detection signal and the reference signal pre-stored in the server 300 on the network. is configured to With this configuration, the configuration of the wire rope inspection device 100 can be simplified compared to the case where the wire rope inspection device 100 (elevator wire rope inspection device) is provided with a storage unit for storing the reference signal. Further, by storing the reference signals in the server 300 on the network, the reference signals corresponding to the plurality of elevators E can be collectively managed (stored).

Further, in the first embodiment, as described above, the differential coil 10 (detection coil) is configured to collectively detect changes in the magnetic fields of the plurality of wire ropes W. FIG. With this configuration, it is possible to easily secure a space for arranging the inspection device, as compared with the case where the inspection device is provided for each of the plurality of wire ropes W.

(Effect of the wire rope inspection method according to the first embodiment)
The following effects can be obtained in the wire rope inspection method of the first embodiment.

In the first embodiment, as described above, the wire rope inspection method (elevator wire rope inspection method) is a difference detection method for detecting changes in magnetic fields of a plurality of elevator wire ropes W that raise and lower the car portion E1 of the elevator E. It includes a step of acquiring a detection signal when the car part E1 moves through one of the plurality of inter-floor intervals (moving interval) by the moving coil 10 (detection coil). Further, the wire rope inspection method includes a detection signal detected by the differential coil 10 and a plurality of reference signals, which are signals detected when the pre-stored cage portion E1 moves through each of the plurality of inter-floor sections. The step of detecting the state of the wire rope W based on the difference from the reference signal corresponding to one inter-floor section is provided. As a result, the reference signal corresponding to each of the plurality of inter-floor sections in which the car portion E1 moves is stored (prepared) in advance. The state of the wire rope W can be detected based on the signal and a pre-stored reference signal corresponding to one inter-floor section. As a result, the start point and the end point of the wire rope W to be inspected by the wire rope inspection apparatus 100 can be aligned in the detection signal and the reference signal for obtaining the difference. Thus, it is possible to provide a wire rope inspection method capable of accurately inspecting the wire rope W even when the car portion E1 of the elevator E moves in an arbitrary inter-floor section.

[Second embodiment]
Next, configurations of a wire rope inspection apparatus 200 and a wire rope inspection method according to the second embodiment will be described with reference to FIGS. 11 and 12. FIG. The wire rope inspection apparatus 200 of the second embodiment differs from the above-described first embodiment in which the reference signal is selected based on the correlation coefficient between the detection signal and the reference signal. A reference signal is selected. In the drawings, the same components as in the first embodiment are indicated by the same reference numerals, and descriptions thereof are omitted.

(Configuration of wire rope inspection device)
As shown in FIG. 11 , the wire rope inspection device 200 has a control section 121 . The wire rope inspection device 200 is an example of the "elevator wire rope inspection device" in the claims.

Here, in the second embodiment, the control unit 121 acquires information (movement information) on the inter-floor section to which the car part E1 has moved. Then, the control unit 121 selects a reference signal corresponding to the acquired inter-floor section information (movement information) from among all the reference signals stored in the server 300 in advance, and selects the reference signal and the detection signal. It is configured to detect the state of the wire rope W based on the difference between .

Also, the control unit 121 acquires information about whether the operation mode of the elevator E is the normal operation mode or the inspection operation mode. The control unit 121 is configured to select a reference signal corresponding to the acquired operation mode information and the movement information. For example, when the car part E1 moves in the inter-floor section from the 1st floor to the 3rd floor in the normal operation mode, the reference signal corresponding to the normal operation mode and the inter-floor section from the 1st floor to the 3rd floor is selected. .

Further, the control unit 121 is configured to detect floor-to-floor information to which the car portion E1 has moved based on position information detected by a position sensor (not shown) provided in the elevator E (car portion E1), for example. good too. Further, the elevator system that manages the elevator E may be configured to transmit to the control unit 121 information on the inter-floor section to which the car part E1 has moved. Further, the control unit 121 may acquire information on the operation mode of the elevator E, for example, based on information on the moving speed detected by a speed sensor (not shown) provided in the elevator E (car portion E1). Further, the elevator system that manages the elevator E may be configured to transmit information regarding the operation mode to the control unit 121 .

(Wire rope inspection method)
Next, a method for inspecting the wire rope W will be described with reference to FIG.

As shown in FIG. 12, the wire rope W inspection method includes a detection signal corresponding to one inter-floor section detected by the differential coil 10, A step (step 303) of detecting the state of the wire rope W based on the difference from the reference signal corresponding to the one inter-floor section is provided. Specifically, the control unit 121 acquires information on the inter-floor section to which the car unit E1 has moved (movement information) and information on the operation mode of the elevator E. FIG. Based on the obtained movement information and driving mode information, the control unit 121 selects a corresponding reference signal from among all the reference signals stored in advance in the server 300 . The controller 121 is configured to calculate the difference between the selected reference signal and the detection signal, and detect the state of the wire rope W based on the calculated difference.

Other configurations of the second embodiment are the same as those of the first embodiment.

(Effect of Second Embodiment)
The following effects can be obtained in the second embodiment.

In the second embodiment, as described above, the control unit 121 acquires information on the inter-floor section (moving section) in which the car part E1 has moved, The state of the wire rope W is detected based on the difference between the selected reference signal and the detection signal by selecting a reference signal corresponding to the information on the interval. With this configuration, compared to the case where the reference signal of the inter-floor interval corresponding to one inter-floor interval is selected based on the correlation coefficient, the processing of calculating the correlation coefficient is unnecessary, and the control unit 121 load can be reduced.

Other effects of the second embodiment are the same as those of the first embodiment.

[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 claims rather than the description of the above-described embodiments, and includes all modifications (modifications) within the scope and meaning equivalent to the scope of claims.

For example, in the above-described first and second embodiments, the controller 21 (121) of the wire rope inspection device 100 (200) detects the state of the wire rope W, but the present invention is limited to this. do not have. For example, a device separate from the wire rope inspection device 100 (200) may perform the above control.

Specifically, as shown in FIG. 13, a wire rope inspection system 500 includes a wire rope inspection device 400 and an external device 900a. The wire rope inspection device 400 has a control section 221 . The external device 900 a also includes a control unit 904 . The wire rope inspection device 400 and the external device 900a are examples of the "elevator wire rope inspection device" and the "control device", respectively. Also, the wire rope inspection system 500 is an example of the "elevator wire rope inspection system" in the claims.

The control unit 221 of the wire rope inspection device 400 controls transmission of the acquired detection signal to the external device 900a.

The control unit 904 acquires the detection signal transmitted from the wire rope inspection device 400 via the communication unit 901 . The external device 900a (control unit 904) outputs a detection signal detected by the differential coil 10 based on the movement of the car E1 in one inter-floor section and a plurality of reference signals stored in advance in the server 300. Based on the difference from the reference signal corresponding to the one movement section, the state of the wire rope W is detected by the control of either the first or second embodiment. An example of the external device 900a may be a terminal such as a PC or a tablet separate from the wire rope inspection device 400, or a server on the network (on the cloud).

Since the reference signal corresponding to each of the plurality of inter-floor sections in which the car E1 moves is stored (prepared) in advance, the car E1 moves in one inter-floor section during the normal operation mode of the elevator E. The detection of the wire rope W can be performed based on the detection signal detected based on what has been done. As a result, the user of the elevator E does not have to move the car E1 of the elevator E from a predetermined start point to a predetermined end point in the inspection operation mode for each inspection to perform measurement. The wire rope W can be detected when the car portion E1 moves by specifying the inter-floor section (moving section). As a result, the wire rope W can be inspected not only in the inspection operation mode of the elevator E but also in the normal operation mode. wire rope inspection system) can be provided.

Further, in the above-described first and second embodiments, an example of detecting the wire rope W based on the detection signal and the reference signal for each inter-floor section was shown, but the present invention is not limited to this. The wire rope W may be detected based on the detection signal and the reference signal for each height (for example, every 10 m) from the ground without using the information on the section between floors.

Further, in the above-described first and second embodiments, the example in which the reference signals corresponding to all the inter-floor sections are stored in advance has been shown, but the present invention is not limited to this. Only reference signals corresponding to some inter-floor intervals among all inter-floor intervals may be stored in advance.

Also, in the above-described first and second embodiments, an example in which the reference signal is stored in the server 300 has been shown, but the present invention is not limited to this. For example, the reference signal may be stored in a storage unit provided in the wire rope inspection device, or an external terminal (smartphone, PC, etc.) different from the wire rope inspection device.

Further, in the first and second embodiments, the magnetic field applying unit 4 is provided only on one side of the wire rope inspection device 100 (200) (elevator wire rope inspection device) in the direction in which the wire rope W extends. Although an example has been given, the invention is not so limited. The magnetic field application units 4 may be provided on both sides of the wire rope inspection device 100 (200) in the direction in which the wire rope W extends. In this case, the reference signal corresponding to the inter-floor interval from the n1 floor to the n2 floor and the reference signal corresponding to the inter-floor interval from the n2 floor to the n1 floor have a symmetrical relationship (in time series). As a result, for example, as the reference signal corresponding to the inter-floor interval from the n2th floor to the n1th floor, the reference signal corresponding to the inter-floor interval from the n1th floor to the n2th floor is reversed (in time series). is possible. In this case, either the reference signal corresponding to the inter-floor interval from the n1 floor to the n2 floor or the reference signal corresponding to the inter-floor interval from the n2 floor to the n1 floor need not be stored in advance. good.

In the first and second embodiments, the differential coil 10 (detection coil) collectively detects changes in the magnetic fields of a plurality of wire ropes W, but the present invention is not limited to this. do not have. For example, a change in the magnetic field of each of the wire ropes W may be individually detected by a plurality of differential coils.

Further, in the first and second embodiments, the differential coil 10 (detection coil) of the wire rope inspection device 100 (200) is configured to collectively detect changes in the magnetic fields of the plurality of wire ropes W. Although an example is shown, the present invention is not limited to this. For example, a differential coil (detection coil) of the wire rope inspection device may be configured to individually detect changes in the magnetic field of each of the plurality of wire ropes. With this configuration, it is possible to easily determine which of the plurality of wire ropes is broken.

Further, the configurations shown in the first and second embodiments are only examples, and the configuration (shape), arrangement, number and material of members, etc. of the wire rope inspection device and the elevator are not limited to these. It can be modified arbitrarily.

[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 a plurality of elevator wire ropes for raising and lowering the car of the elevator;
a control unit that receives a detection signal of the wire rope acquired by the detection coil,
The control unit generates a detection signal detected by the detection coil based on the movement of the cage in one movement section of a plurality of movement sections, and The state of the wire rope is detected based on a difference from the reference signal corresponding to the one movement section, among a plurality of reference signals detected when moving through each section. A wire rope inspection device for elevators, comprising:

(Item 2)
The moving section includes an inter-floor section that is a section from one floor to another floor of the building where the elevator is installed,
The control unit controls the detection signal of the wire rope detected by the detection coil based on the movement of the car in one of the inter-floor sections, and The state of the wire rope is detected based on the difference from the reference signal corresponding to the one inter-story section among the plurality of reference signals detected when moving through each inter-story section. The elevator wire rope inspection device according to item 1, wherein the elevator wire rope inspection device is configured to:

(Item 3)
The control unit corresponds to the detection signal of the wire rope detected by the detection coil based on the movement of the car in one of the inter-floor sections and all of the pre-stored inter-floor sections. The elevator wire according to item 2, wherein the state of the wire rope is detected based on a difference from the reference signal corresponding to the one inter-floor section, among the reference signals corresponding to the Rope inspection device.

(Item 4)
The control unit pre-stores the detection signal detected by the detection coil based on the movement of the car in one of the plurality of movement sections during the normal operation mode of the elevator. of the plurality of reference signals, which are signals detected when the car portion moves in each of the plurality of movement sections during the normal operation mode of the elevator, which corresponds to the one movement section 4. The elevator wire rope inspection device according to any one of items 1 to 3, configured to detect the state of the wire rope based on a difference from a reference signal.

(Item 5)
In addition to detecting the wire rope during the normal operation mode, the control unit detects that the cage moves the plurality of movements during an inspection operation mode in which the elevator moves at a lower moving speed of the cage than during the normal operation mode. The detection signal detected by the detection coil based on the movement of the one moving section among the sections, and the pre-stored inspection operation mode of the elevator in which the car is in the plurality of moving sections. The state of the wire rope is detected based on a difference from the reference signal corresponding to the one movement section, among the plurality of reference signals detected when each movement is performed. 5. The elevator wire rope inspection device according to item 4.

(Item 6)
The control unit selects the reference signal having the maximum correlation coefficient with the detection signal from among the plurality of reference signals stored in advance, and selects a difference between the selected reference signal and the detection signal. The elevator wire rope inspection device according to any one of items 1 to 5, which is configured to detect the state of the wire rope based on.

(Item 7)
The control unit acquires information on the movement section in which the basket moves, and selects the reference signal corresponding to the acquired information on the movement section from among the plurality of reference signals stored in advance, The elevator wire rope inspection device according to any one of items 1 to 5, configured to detect the state of the wire rope based on the difference between the selected reference signal and the detection signal. .

(Item 8)
Any one of items 1 to 7, wherein the control unit is configured to detect the state of the wire rope based on a difference between the detection signal and the reference signal pre-stored in a server on a network. 1. A wire rope inspection device for elevators according to claim 1.

(Item 9)
The elevator wire rope inspection device according to any one of items 1 to 8, wherein the detection coil is configured to collectively detect changes in the magnetic fields of the plurality of wire ropes.

(Item 10)
The elevator wire rope inspection device according to any one of items 1 to 8, wherein the detection coil is configured to individually detect changes in the magnetic field of each of the plurality of wire ropes.

(Item 11)
an elevator wire rope inspection device including a detection coil for detecting changes in a magnetic field of a plurality of elevator wire ropes for raising and lowering an elevator car;
a control device that receives a detection signal of the wire rope acquired by the detection coil,
The control device outputs a detection signal detected by the detection coil based on the movement of the cage through one movement section of a plurality of movement sections, and The state of the wire rope is detected based on a difference from the reference signal corresponding to the one movement section, among a plurality of reference signals detected when moving through each section. A wire rope inspection system for elevators, comprising:

(Item 12)
A detection signal is obtained when the car moves in one of a plurality of moving sections using a detection coil that detects changes in the magnetic field of a plurality of wire ropes W for elevators that raise and lower the car of the elevator. and
The one movement among the detection signal detected by the detection coil and a plurality of reference signals that are signals detected when the cage moves in each of the plurality of movement sections stored in advance. and detecting the state of the wire rope based on the difference from the reference signal corresponding to the section.

10 differential coil (detection coil)
21, 121 control unit 100, 200, 400 wire rope inspection device (elevator wire rope inspection device)
102 building 300 server 900a external device (control device)
E Elevator E1 Basket W Wire rope

Claims (12)

a detection coil for detecting changes in the magnetic field of a plurality of elevator wire ropes for raising and lowering the car of the elevator;
a control unit that receives a detection signal of the wire rope acquired by the detection coil,
The control unit generates a detection signal detected by the detection coil based on the movement of the cage in one movement section of a plurality of movement sections, and The state of the wire rope is detected based on a difference from the reference signal corresponding to the one movement section, among a plurality of reference signals detected when moving through each section. A wire rope inspection device for elevators, comprising: The moving section includes an inter-floor section that is a section from one floor to another floor of the building where the elevator is installed,
The control unit controls the detection signal of the wire rope detected by the detection coil based on the movement of the car in one of the inter-floor sections, and The state of the wire rope is detected based on the difference from the reference signal corresponding to the one inter-story section among the plurality of reference signals detected when moving through each inter-story section. 2. The elevator wire rope inspection device of claim 1, wherein the elevator wire rope inspection device is configured to: The control unit corresponds to the detection signal of the wire rope detected by the detection coil based on the movement of the car in one of the inter-floor sections and all of the pre-stored inter-floor sections. 3. The elevator according to claim 2, wherein the state of the wire rope is detected based on a difference between the reference signal corresponding to the one inter-floor section and the reference signal corresponding to the one floor section. Wire rope inspection equipment. The control unit pre-stores the detection signal detected by the detection coil based on the movement of the car in one of the plurality of movement sections during the normal operation mode of the elevator. of the plurality of reference signals, which are signals detected when the car portion moves in each of the plurality of movement sections during the normal operation mode of the elevator, which corresponds to the one movement section The elevator wire rope inspection device according to any one of claims 1 to 3, configured to detect the state of the wire rope based on a difference from a reference signal. In addition to detecting the wire rope during the normal operation mode, the control unit detects the movement of the cage during the inspection operation mode of the elevator in which the moving speed of the cage is smaller than that during the normal operation mode. The detection signal detected by the detection coil based on the movement of the one moving section among the sections, and the pre-stored inspection operation mode of the elevator in which the car is in the plurality of moving sections. The state of the wire rope is detected based on a difference from the reference signal corresponding to the one movement section, among the plurality of reference signals detected when each movement is performed. The elevator wire rope inspection device according to claim 4, wherein: The control unit selects the reference signal having the maximum correlation coefficient with the detection signal from among the plurality of reference signals stored in advance, and selects a difference between the selected reference signal and the detection signal. The elevator wire rope inspection device according to any one of claims 1 to 5, configured to detect the state of the wire rope based on. The control unit acquires information on the movement section in which the basket moves, and selects the reference signal corresponding to the acquired information on the movement section from among the plurality of reference signals stored in advance, The elevator wire rope inspection according to any one of claims 1 to 5, configured to detect the state of the wire rope based on the difference between the selected reference signal and the detection signal. Device. The controller according to any one of claims 1 to 7, wherein the control unit is configured to detect the state of the wire rope based on a difference between the detection signal and the reference signal pre-stored in a server on a network. The wire rope inspection device for elevators according to any one of claims 1 to 3. The elevator wire rope inspection device according to any one of claims 1 to 8, wherein the detection coil is configured to collectively detect changes in the magnetic fields of the plurality of wire ropes. The elevator wire rope inspection device according to any one of claims 1 to 8, wherein the detection coil is configured to individually detect changes in the magnetic field of each of the plurality of wire ropes. an elevator wire rope inspection device including a detection coil for detecting changes in a magnetic field of a plurality of elevator wire ropes for raising and lowering an elevator car;
a control device that receives a detection signal of the wire rope acquired by the detection coil,
The control device outputs a detection signal detected by the detection coil based on the movement of the cage through one movement section of a plurality of movement sections, and The state of the wire rope is detected based on a difference from the reference signal corresponding to the one movement section, among a plurality of reference signals detected when moving through each section. A wire rope inspection system for elevators, comprising: A detection signal is acquired when the car moves in one of a plurality of moving sections by means of a detection coil that detects changes in the magnetic field of a plurality of wire ropes for elevators that raise and lower the car of the elevator. process and
The one movement out of the detection signal detected by the detection coil and a plurality of reference signals which are signals detected when the cage moves in each of the plurality of movement sections stored in advance. and detecting the state of the wire rope based on the difference from the reference signal corresponding to the section.

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