JP5832258B2 - Elevator abnormality diagnosis device - Google Patents

Description

  The present invention relates to an elevator abnormality diagnosis apparatus that diagnoses an abnormality that has occurred in an elevator.

  The conventional elevator abnormality diagnosis device detects sound and vibration generated by the operation of the elevator with a sound vibration sensor, stores the operation state of the elevator when sound and vibration exceeding a preset reference value are detected, When this operating state is reproduced by the elevator, if a sound or vibration exceeding the reference value is detected again, an abnormality is diagnosed. If the sound is below the reference value, it is determined that the sound or vibration is not an abnormality but transient. (For example, refer to Patent Document 1).

JP 2008-24420 A

In the conventional technique represented by Patent Document 1, abnormality determination is performed by comparing the result of both sound and vibration detected by a sensor with a preset reference value.
However, noise and vibration generated during elevator operation vary depending on the combination of elevator specifications (elevating speed, pulley diameter, car weight, rope length, elevating stroke, property use, etc.). For this reason, when an unknown abnormality is also taken into consideration, it is impossible to previously set a reference value for uniquely determining whether or not the sound and vibration generated during the operation of the elevator are abnormal.
Therefore, when the reference value is set high in order to reduce misdiagnosis, even if sound or vibration is generated to the extent that the elevator user feels abnormal, the abnormality may not be detected on the apparatus side. On the other hand, when the reference value is set low in order to prevent detection omission, there is a possibility that even if the sound and vibration are normal in the elevator specifications, it is determined that the reproduction operation is abnormal.

  The present invention has been made to solve the above-described problems, and an object of the present invention is to provide an elevator abnormality diagnosis device that can reduce misdiagnosis caused by differences in elevator specifications.

  An elevator abnormality diagnosis apparatus according to the present invention inputs waveform data of sounds and vibrations detected in an elevator car, generates analysis data obtained by analyzing the waveform data, and specification data relating to the diagnosis target elevator On the other hand, the multidimensional data generation unit that generates multidimensional data in which the analysis data generated by the waveform analysis unit for the elevator is associated, and the sound and vibration of the elevator with respect to the specification data of the elevator having no abnormality Calculated by a Mahalanobis distance calculator that calculates a Mahalanobis distance between a reference space composed of multidimensional data associated with analysis data and the multidimensional data generated by the multidimensional data generator, and a Mahalanobis distance calculator. Compare the Mahalanobis distance with a predetermined threshold, and the Mahalanobis distance is greater than the threshold. The elevator when There are judged to be abnormal, and a and determination unit Mahalanobis distance is normal if less than the threshold value.

  According to the present invention, there is an effect that misdiagnosis caused by a difference in elevator specifications can be reduced.

1 is a block diagram illustrating a configuration of an elevator abnormality diagnosis system to which an elevator abnormality diagnosis device according to Embodiment 1 of the present invention is applied. It is a figure which shows the specification data stored in a specification data storage part. It is a block diagram which shows the structure of the elevator abnormality diagnostic apparatus which concerns on Embodiment 1, and its periphery part. It is a figure which shows the analysis data which consists of an element computed in the waveform analysis part. It is a figure which shows the multidimensional data which consist of specification data and waveform analysis data. It is a graph which shows the average value and standard deviation for every item produced | generated during the process of the Mahalanobis distance calculation part from multidimensional data. It is a figure which shows standardization data. It is a graph which shows the reference | standard space and Mahalanobis distance of normal data and abnormal data. 6 is a flowchart showing an operation (part 1) of the elevator abnormality diagnosis device according to the first embodiment. 6 is a flowchart showing an operation (part 2) of the elevator abnormality diagnosis device according to the first embodiment. It is a block diagram which shows the structure of the elevator abnormality diagnostic apparatus which concerns on Embodiment 2 of this invention, and its periphery part.

Embodiment 1 FIG.
1 is a block diagram showing a configuration of an elevator abnormality diagnosis system to which an elevator abnormality diagnosis device according to Embodiment 1 of the present invention is applied. In FIG. 1, an elevator abnormality diagnosis device 1 according to Embodiment 1 is provided in a management center 2 and diagnoses an abnormality of an elevator in a hoistway 3 using data stored in a maintenance management database 20.
The maintenance management database 20 is a standard composed of multi-dimensional data in which analysis data of sound and vibration in the elevator is associated with the specification data of the elevator having no abnormality in addition to the specification data of the elevator to be subjected to abnormality diagnosis. It is a database that stores space.
As shown in FIG. 2, the elevator specification data 61 includes the number of floors, capacity, rated speed, maximum speed, diameter of each pulley, lifting stroke, rail length, rope length, number of ropes, car mass, counter mass, There is a car capacity, etc., and a unique identification number is given to these data and stored for each elevator to be subjected to abnormality diagnosis.

The elevator components provided in the hoistway 3 include a car 30, a counterweight 31, a hoisting machine 32, and a sound / vibration detector 33. The car 30 and the counterweight 31 are wound around the hoistway 3 by a rope and are moved up and down by a hoisting machine 32.
The sound / vibration detector 33 is provided in the car 30 and detects and generates sound and vibration generated by the car 30, the counterweight 31, the hoist 32, and elevator components (not shown) during operation of the elevator. Further, data communication is performed by the communication means 4 between the sound / vibration detector 33 and the elevator abnormality diagnosis device 1. The communication method of the communication means 4 may be wired or wireless. The elevator abnormality diagnosis device 1 of the management center 2 receives the sound and vibration data detected by the sound / vibration detector 33 via the communication means 4.

  FIG. 3 is a block diagram illustrating a configuration of the elevator abnormality diagnosis apparatus according to the first embodiment and its peripheral part. In FIG. 3, the elevator abnormality diagnosis apparatus 1 includes a waveform analysis unit 10, a multidimensional data generation unit 11, a Mahalanobis distance calculation unit 12, and an abnormality determination unit 13. The maintenance management database 20 includes a specification data storage unit 201 and a reference space storage unit 202. Furthermore, the sound / vibration detector 33 in the hoistway 3 includes a microphone 331, an acceleration sensor 332, and a measurement data storage unit 333.

The waveform analysis unit 10 in the elevator abnormality diagnosis apparatus 1 reads sound and vibration data stored in the measurement data storage unit 332 via the communication unit 4 and performs waveform analysis on the sound and vibration waveform data. Generate analysis data. For example, the vibration amplitude value and the traveling speed are calculated from the vibration waveform data, the maximum value and the average value of the frequency intensity for each specified frequency band are calculated from the sound waveform data, and these calculation results and each elevator are given. Analysis data 71 as shown in FIG. 4 is generated with a unique identification number as an element.
The multi-dimensional data generation unit 11 generates multi-dimensional data 81 shown in FIG. 5 in which the analysis data 71 generated by the waveform analysis unit 10 is associated with the specification data of the elevator to be diagnosed for abnormality by mutual identification numbers. To do.

The specification data storage unit 201 of the maintenance management database 20 is a storage unit that stores specification data for each elevator subject to abnormality diagnosis.
The reference space storage unit 202 is a storage unit that stores a reference space composed of multi-dimensional data in which analysis data of sound and vibration in the elevator is associated with specification data of the elevator having no abnormality.
The reference space is generated as follows.
First, the number of items (X _{11 to} X _n1 ) of the reference data 91 shown in FIG. 6 configured by removing the identification number and the date and time of data collection from the multi-dimensional data 81 of a normal elevator collected in advance, ascending and descending stroke _{(X 12 ~X n2), ···} , sounds largest respective average _m 1 of _{(X 1k ~X nk), m} 2, ···, m k and the standard deviation σ _1, σ _2, ··· , Σ _k, and normalization is performed according to the following equation (1). The result is standardized data 101 as shown in FIG.
Next, a correlation matrix of the standardized data 101 is obtained. The correlation matrix R is obtained according to the following equation (2), and the element r _{ij of the} correlation matrix is obtained according to the following equation (3).
A reference space is obtained by converting the correlation matrix R obtained from the following formula (2) and the following formula 3 into an inverse matrix according to the following formula (4). This reference space is stored in the reference space storage unit 202.

The Mahalanobis distance calculation unit 12 is generated by a multi-dimensional data generation unit 11 including a reference space composed of multi-dimensional data in which analysis data of sound and vibration in the elevator is associated with specification data of an elevator having no abnormality. The Mahalanobis distance with the obtained multidimensional data is calculated.
The Mahalanobis distance is calculated according to the following formula (5). Here, k is the number of items in the reference space. In (x ₁ , x ₂ ,..., X _k ) in the following formula (5), the multidimensional data 81 of the elevator to be subjected to abnormality diagnosis for obtaining the Mahalanobis distance from the reference space is input. At this time, the same item as that used when creating the reference space is input without including the identification number of the multidimensional data 81 and the data collection date and time.
FIG. 8 shows a reference space generated from multi-dimensional data of 160 normal elevators and 14 multi-dimensional data 81 of normal elevators and abnormal elevators as targets of abnormality diagnosis. It is the Mahalanobis distance calculation result 111 which graphed the result inputted one by one.
The abnormality determination unit 13 compares the Mahalanobis distance calculated by the Mahalanobis distance calculation unit 12 with a predetermined threshold value, determines that the Mahalanobis distance exceeds a predetermined threshold value, and determines that there is an abnormality, and does not exceed the threshold value (below the threshold value). Is determined to be normal.

The specification data storage unit 201 of the maintenance management database 20 is a storage unit that stores specification data for each elevator subject to abnormality diagnosis.
The reference space storage unit 202 is a storage unit that stores a reference space composed of multi-dimensional data in which analysis data of sound and vibration in the elevator is associated with specification data of the elevator having no abnormality.

  The microphone 331 of the sound / vibration detector 33 is a sound collector that collects sound generated while the car 30 is traveling in the hoistway 3. The acceleration sensor 332 is a vibration acceleration sensor that detects vibration generated in the car 30 traveling in the hoistway 3. The measurement data storage unit 333 is a storage unit that stores sound data collected by the microphone 331 and vibration data detected by the acceleration sensor 332.

Next, the operation will be described.
(1) Case where Predictive Diagnosis is not Performed FIG. 9 is a flowchart showing the operation of the elevator abnormality diagnosis device according to Embodiment 1, and shows a case where predictive diagnosis is not performed.
First, in the elevator to be diagnosed, the microphone 331 in the sound / vibration detector 33 collects sound generated while the car 30 is traveling in the hoistway 3, and the acceleration sensor 332 is used in the hoistway 3. The vibration generated in the car 30 traveling inside is detected (step ST1).
The sound and vibration data measured by the sound / vibration detector 33 is stored in the measurement data storage unit 333.

Next, the waveform analysis unit 10 of the elevator abnormality diagnosis device 1 reads the waveform data of the elevator sound and vibration of the abnormality diagnosis target stored in the measurement data storage unit 333 via the communication unit 4, and the sound and vibration Analysis data obtained by waveform analysis of the above data is generated (step ST2).
For example, from the vibration waveform data measured by the sound / vibration detector 33, the vibration amplitude value and the traveling speed of the car 30 are calculated, the frequency analysis of the sound waveform data is performed, and the constant specified from the sound waveform data is obtained. Matrix data including a peak value (maximum value; sound maximum in FIG. 4) and an average value (sound average in FIG. 4) of the frequency intensity calculated for each frequency band.

  Subsequently, the multidimensional data generation unit 11 associates the analysis data generated by the waveform analysis unit 10 with the specification data of the abnormality diagnosis target elevator read from the specification data storage unit 201 of the maintenance management database 20. Multidimensional data is generated (step ST3). For example, as shown in FIG. 5, each element of the matrix of the analysis data 71 is associated with each data element in the specification data 61.

  Thereafter, the Mahalanobis distance calculation unit 12 calculates the Mahalanobis distance between the reference space read from the reference space storage unit 202 of the maintenance management database 20 and the multidimensional data generated by the multidimensional data generation unit 11 (step ST4). ). For example, as shown in FIG. 8, the Mahalanobis distance is calculated according to the above equation (5).

The abnormality determination unit 13 compares the Mahalanobis distance calculated by the Mahalanobis distance calculation unit 12 with a predetermined threshold value, and determines whether the Mahalanobis distance exceeds the predetermined threshold value (step ST5). Here, when the Mahalanobis distance exceeds a predetermined threshold (step ST5; YES), the abnormality determination unit 13 determines that the elevator is abnormal, and notifies the elevator maintenance staff that there is an abnormality (step ST6). ). At this time, the car 30 is urgently stopped, and the operation is stopped until the inspection of the elevator maintenance staff is performed. Alternatively, the elevator may be stopped at the nearest floor and the operation may be stopped after the passengers get off.
On the other hand, when the Mahalanobis distance is less than the predetermined threshold (step ST5; NO), the abnormality determination unit 13 determines that the elevator is normal and notifies the elevator maintenance staff (step ST7).

(2) Case where Predictive Diagnosis is Performed FIG. 10 is a flowchart showing the operation of the elevator abnormality diagnosis apparatus according to Embodiment 1, and shows a case where predictive diagnosis is performed. In FIG. 10, the process from step ST1 to step ST5 and the process of step ST6 and step ST7 are the same as those in FIG. The abnormality determination unit 13 that performs the predictive diagnosis sequentially stores the timer that measures the time interval at which the abnormality diagnosis is performed and the Mahalanobis distance that is calculated by the Mahalanobis distance calculation unit 12 every time the abnormality diagnosis is performed. Assume that a memory is provided.

  When the Mahalanobis distance is less than the predetermined threshold (step ST5; NO), the abnormality determination unit 13 reads the Mahalanobis distance calculated in the previous abnormality diagnosis from the memory, and the current Mahalanobis distance is larger than the previous Mahalanobis distance. Whether or not (step ST5-1). If the current Mahalanobis distance is less than or equal to the previous Mahalanobis distance (step ST5-1; NO), the abnormality determining unit 13 determines that the elevator is normal and proceeds to step ST7.

On the other hand, when the current Mahalanobis distance is greater than the previous time (step ST5-1; YES), the abnormality determination unit 13 first determines the elapsed time from the previous time measured by the timer to the current abnormality diagnosis, the current time and the previous time. The amount of change (differential value) with respect to the unit time of the previous and current Mahalanobis distances is calculated using the difference between the Mahalanobis distances.
Next, the abnormality determination unit 13 calculates an elapsed time until the Mahalanobis distance exceeds the threshold used in step ST5 when the Mahalanobis distance is increased from the current Mahalanobis distance by the amount of change, and the elapsed time is added to the current time. The due date is predicted as the next inspection date.
Thereafter, the abnormality determination unit 13 notifies the elevator maintenance staff of the normality in the current abnormality diagnosis and the predicted inspection date (step ST5-2).

  In addition, the notification method in step ST6, step ST7, and step ST5-2 is not shown because the worker in the management center 2 or the maintenance staff of the elevator subject to abnormality diagnosis can recognize the diagnosis result. You may notify to a container, and you may notify to the portable terminal which an operator has.

As described above, according to the first embodiment, the waveform analysis unit 10 that inputs the sound and vibration waveform data detected by the elevator car 30 and generates analysis data obtained by analyzing the waveform data, and diagnosis With respect to the specification data regarding the target elevator, the multi-dimensional data generation unit 11 that generates multi-dimensional data in which the analysis data generated by the waveform analysis unit 10 for the elevator is associated, and the specification data of the elevator with no abnormality A Mahalanobis distance calculation unit that calculates a Mahalanobis distance between a reference space composed of multidimensional data in which analysis data of sound and vibration in the elevator is associated with the multidimensional data generated by the multidimensional data generation unit 11 12 and the Mahalanobis distance calculated by the Mahalanobis distance calculation unit 12 are compared with a predetermined threshold, The elevator is determined to be abnormal Haranobisu distance is larger than the threshold, and an abnormality determination unit 13 determines that the Mahalanobis distance is normal if less than the threshold value. With this configuration, it is possible to reduce misdiagnosis caused by differences in elevator specifications without causing variations in threshold values that become abnormal due to the specifications of the elevator.
For the multidimensional data in the reference space, it is sufficient to use sound and vibration waveform data in which a person is riding on the car and both the sound and vibration are determined to be normal, and for determining abnormality for each sound and vibration data. There is no need to determine a threshold.

  Further, according to the first embodiment, the specification data includes the number of floors, capacity, rated speed, maximum speed, diameter of each pulley, lifting stroke, rail length, rope length, number of ropes, and car mass in the elevator to be diagnosed. Because of the counter mass and car capacity, it is possible to accurately diagnose abnormalities according to various specifications of the elevator.

  Furthermore, according to the first embodiment, the waveform analysis unit 10 determines the vibration amplitude value, the traveling speed of the car 30 and the waveform data of the sound detected by the car 30 from the vibration waveform data detected by the elevator car 30. The maximum value and the average value of the frequency intensity for each frequency band designated from the above are calculated, and a matrix having these calculation results as elements is generated as analysis data. By doing so, it is possible to accurately reflect the sound and vibration characteristics detected by the traveling car 30 in the abnormality diagnosis.

  Furthermore, according to the first embodiment, the abnormality determination unit 13 uses the elapsed time from the previous time to the current diagnosis and the difference between the previous time and the current Mahalanobis distance calculated by the Mahalanobis distance calculation unit 12 to determine the previous time. And the amount of change of the current Mahalanobis distance per unit time is calculated, the elapsed time until the Mahalanobis distance becomes larger than the threshold when the current Mahalanobis distance is increased by the amount of change is calculated, and the elapsed time at the current time is calculated. The due date with the time added is the date to be checked next time. By doing in this way, the estimated day can be used as a standard of the next inspection day.

Embodiment 2. FIG.
In the first embodiment, the case where the sound / vibration detector 33 is provided separately from the elevator abnormality diagnosis apparatus 1 and the elevator abnormality diagnosis apparatus 1 is disposed in the management center 2 has been described. Then, the structure which provided the elevator abnormality diagnostic apparatus incorporating the sound and the vibration detector in the hoistway is described.

  FIG. 11 is a block diagram showing the configuration of the elevator abnormality diagnosis device and its peripheral part according to Embodiment 2 of the present invention. In FIG. 11, an elevator abnormality diagnosis apparatus 1A according to the second embodiment is an apparatus that is provided in the hoistway 3 and diagnoses an abnormality of the elevator, and includes a microphone 14, an acceleration sensor 15, a measurement data storage unit 16, and a waveform analysis. Unit 10, multidimensional data generation unit 11, Mahalanobis distance calculation unit 12, and abnormality determination unit 13.

  The microphone 14 is a sound collector that collects sound generated while the car 30 is traveling in the hoistway 3, and has the same function as the microphone 331 of the sound / vibration detector 33 in FIG. The acceleration sensor 15 is a vibration acceleration sensor that detects vibration generated in the car 30 traveling in the hoistway 3, and has the same function as the acceleration sensor 332 of the sound / vibration detector 33 in FIG. The measurement data storage unit 16 is a storage unit that stores sound data collected by the microphone 14 and vibration data detected by the acceleration sensor 15, and is similar to the measurement data storage unit 333 of the sound / vibration detector 33 in FIG. Function.

The waveform analysis unit 10 and the abnormality determination unit 13 are the same as those in FIG.
The multidimensional data generation unit 11 accesses the maintenance management database 20 in the management center 2 via the communication unit 4, reads the specification data of the elevator to be diagnosed from the specification data storage unit 201, and uses the specification data as the specification data. On the other hand, multidimensional data in which the analysis data generated by the waveform analysis unit 10 is associated is generated.
Similarly, the Mahalanobis distance calculation unit 12 accesses the maintenance management database 20 in the management center 2 via the communication unit 4, and the reference space storage unit 202 receives the sound in the elevator from the standard specification data of the elevator having no abnormality. Is read out, and the Mahalanobis distance between the reference space and the multidimensional data generated by the multidimensional data generation unit 11 is calculated.
Thereby, the elevator abnormality diagnosis device 1A according to the second embodiment can perform the processes of FIGS. 9 and 10 shown in the first embodiment.

  The elevator abnormality diagnosis device 1A according to the second embodiment is applied to a communication device capable of communicating with the maintenance management database 20 in the management center 2, a portable terminal (for example, a smartphone) having the microphone 14 and the acceleration sensor 15. Is possible. In this case, since the operation of installing the abnormality diagnosis system in the elevator is completed simply by attaching the portable terminal to the car 30, the burden on the worker can be reduced.

As described above, according to the second embodiment, the microphone 14 that collects the waveform data of the sound generated in the elevator car 30, the acceleration sensor 15 that detects the waveform data of the vibration generated in the car 30, and the diagnosis A maintenance management database 20 that stores specification data related to the target elevator and a reference space and a communication means 4 that performs data communication are provided, and the multidimensional data generation unit 11 performs diagnosis from the maintenance management database 20 via the communication means 4. The specification data regarding the elevator is acquired, and the Mahalanobis distance calculation unit 12 acquires the reference space from the maintenance management database 20 via the communication unit 4.
In this way, by combining the configuration of the sound / vibration detector 33 and the configuration of the elevator abnormality diagnosis device, the same effect as in the first embodiment can be obtained.
Further, by applying the elevator abnormality diagnosis apparatus 1A according to the second embodiment to a portable terminal having a communication means capable of data communication with the maintenance management database 20 in the management center 2, and the microphone 14 and the acceleration sensor 15, The work of installing the abnormality diagnosis system in the elevator is only to attach the portable terminal to the car 30, and the work load can be reduced.

  In the present invention, within the scope of the invention, any combination of each embodiment, any component of each embodiment can be modified, or any component can be omitted in each embodiment. .

  DESCRIPTION OF SYMBOLS 1,1A Elevator abnormality diagnosis apparatus, 2 management center, 3 hoistway, 4 communication means, 10 waveform analysis part, 11 multidimensional data generation part, 12 Mahalanobis distance calculation part, 13 abnormality determination part, 14,331 microphone, 15, 332 acceleration sensor, 16,333 measurement data storage unit, 20 maintenance management database, 30 car, 31 counterweight, 32 hoisting machine, 33 sound / vibration detector, 61 specification data, 71 analysis data, 81 multidimensional data, 91 standard Data, 101 standardized data, 111 Mahalanobis distance calculation result, 201 specification data storage unit, 202 reference space storage unit.

Claims (5)

A waveform analysis unit that inputs sound and vibration waveform data detected in an elevator car and generates analysis data obtained by analyzing the waveform data;
A multidimensional data generation unit that generates multidimensional data in which the analysis data generated by the waveform analysis unit for the elevator is associated with the specification data related to the elevator to be diagnosed;
A reference space composed of multidimensional data in which analysis data of sound and vibration in the elevator is associated with specification data of an elevator having no abnormality, and multidimensional data generated by the multidimensional data generation unit A Mahalanobis distance calculator for calculating the Mahalanobis distance;
Comparing the Mahalanobis distance calculated by the Mahalanobis distance calculation unit with a predetermined threshold value, it is determined that the elevator is abnormal when the Mahalanobis distance is greater than the threshold value, and the Mahalanobis distance is equal to or less than the threshold value. If it is, an elevator abnormality diagnosis apparatus provided with the determination part determined to be normal. A sound collection unit for collecting waveform data of sounds generated in the elevator car;
A vibration acceleration detector for detecting waveform data of vibration generated in the car;
A communication unit that performs data communication with a maintenance management database that stores specification data about the elevator to be diagnosed and the reference space;
The multi-dimensional data generation unit acquires specification data relating to the diagnosis target elevator from the maintenance management database via the communication unit,
The elevator abnormality diagnosis apparatus according to claim 1, wherein the Mahalanobis distance calculation unit acquires the reference space from the maintenance management database via the communication unit.   The specification data includes the number of floors, capacity, rated speed, maximum speed, pulley diameter, lifting stroke, rail length, rope length, number of ropes, car mass, counter mass, and car capacity in the elevator to be diagnosed. The elevator abnormality diagnosis apparatus according to claim 1 or 2, characterized in that   The waveform analysis unit includes a vibration amplitude value and a running speed of the car from the vibration waveform data detected in the elevator car, and a frequency for each frequency band specified from the sound waveform data detected in the elevator car. The elevator abnormality diagnosis apparatus according to any one of claims 1 to 3, wherein a maximum value and an average value of the intensity are calculated, and a matrix having these calculation results as elements is generated as analysis data. .   The determination unit uses the elapsed time from the previous to the current diagnosis and the difference between the previous and current Mahalanobis distances calculated by the Mahalanobis distance calculation unit to calculate the amount of change of the previous and current Mahalanobis distances per unit time. Calculate and calculate the elapsed time until the Mahalanobis distance increases above the threshold when the current Mahalanobis distance is increased by the amount of change, and the next date should be checked by adding the elapsed time to the current time The elevator abnormality diagnosis device according to any one of claims 1 to 4, wherein the elevator abnormality diagnosis device is a day.

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