JPH0737186A - Elevator fault predicting system - Google Patents

Abstract

PURPOSE:To lighten the burden on a monitoring operator and a computer, and to lose no time to start maintenance work by detecting, specifying abnormality and predicting the occurring date of a fault by a diagnostic control part. CONSTITUTION:The sign judging part 14 of the diagnostic control part 1 compares collected diagnostic data with the sign judgement value of the fault, and when that diagnostic data exceeds a prescribed sign judgement value, it judges an elevator to become defective in the future, and specifies an abnormal machine, and predicts the occurring date of that fault, and stores these results in a storage part 15. Next, in the case that sign data stored in the storage part 15 satisfies a prescribed condition set beforehand, a CPU 11 communicates the prior sign data to a diagnostic sensor 2 through communication equipment 16. This diagnostic sensor 2 is provided with a maintenance work instruction storage part 24 in which the work instruction of maintenance classified by the prior sign data is stored, and a work instruction issuance judging part 25 to judge whether or not a work instruction is to be issued and so on, and outputs the predicitve fault occurring date of the elevator predicted by the diagnostic control part 1 to a business office 3.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an elevator failure sign system suitable for detecting signs of elevator failure and performing maintenance work before the failure.

[0002]

2. Description of the Related Art In the conventional inspection of elevators, maintenance personnel regularly go to the building, board the elevator car, operate the operation panel manually to perform periodic inspections, and prevent the breakdown from occurring. It was However, in recent years, for such an inefficient maintenance system by the maintenance personnel, for example, Japanese Patent Laid-Open No.
As described in JP-A-0-244782, an elevator inspection system has been proposed which automatically inspects an elevator using a sensor or a microcomputer. According to this elevator inspection system, a microcomputer with an automatic inspection function that manages the operating state of the elevator uses a sensor that detects steady performance such as the degree of elevator elevator, functional changes such as landing level, and external environment such as temperature. The information data of the above is collated with a predetermined reference value for equipment maintenance, and if it is not the reference value, it is stored in the memory as an abnormality detection, and the contents of this memory are read out via the transmission device according to the abnormality detection content. I am going to perform a check.

Further, in the one disclosed in Japanese Patent Laid-Open No. 4-201963, monitoring data of an arbitrary elevator is collected by a monitoring center device, a failure diagnosis is made by a failure diagnosis program in the monitoring center device, and necessary maintenance work is output. A system to do this has been proposed.

[0004]

However, in the former system, although the abnormality of the equipment is detected, the observer judges the timing of the maintenance work for the equipment that has detected the abnormality.
Judgment may differ due to differences in the technical knowledge and experience of the observers, and if there is a possibility that maintenance work may be delayed and a failure may occur. Also in the latter system, a monitoring center that monitors tens of thousands of elevators remotely collects all the minor abnormal data and performs failure diagnosis one by one, so that the load on the monitoring center device is great. Not only that, but it also takes a considerable amount of time and line cost to collect abnormal data for failure diagnosis.

An object of the present invention is to provide an elevator failure signage system that reduces the load on the monitoring center device and does not miss the timing of performing maintenance work on equipment that has detected an abnormality.

[0006]

In order to achieve the above-mentioned object, the present invention provides an elevator failure sign system in which a plurality of elevator control diagnostic units and a sales office are connected by a diagnostic center. The department collects diagnostic data during operation of the elevator, and detects anomalies based on the diagnostic data, and predicts the date of failure detection and the identification of abnormal equipment. Means for transmitting the sign data of the sign data to the diagnostic center, and the diagnostic center has means for sending sign work instruction information for each content of the sign data sent from each of the diagnostic centers to the sales office. , The above office is
It is characterized by further comprising output means for outputting a predictive work instruction sheet based on the predictive work instruction information sent from the diagnostic center.

[0007]

The elevator failure sign system according to the present invention comprises:
Based on the collected diagnostic data, the control diagnosis unit detects equipment abnormalities, identifies the abnormal equipment and predicts the elevator failure date, sends the predicted predictive data to the monitoring center, and the monitoring center sends it. Depending on the contents of the predictive data, the predictive work instruction is issued to the sales office in charge of maintenance, so the sales office performs appropriate maintenance work based on the predictive work instruction before the elevator fails. Since the sign data is output from the control diagnosis unit, the load on the monitoring center device can be reduced.

[0008]

Embodiments of the present invention will be described below with reference to the drawings.
FIG. 1 is a block diagram showing a main part of an elevator failure sign system according to an embodiment of the present invention. A plurality of control diagnosis units 1 each of which is connected to an elevator control device and predicts a failure of the elevator sends predictive data to the diagnostic center 2, and the plurality of diagnostic centers 2 provide predictive work instruction information corresponding to the predictive data in charge of sales. To the station 3, and the communication devices 16, 27, 28, and 35 are connected between them. The control diagnosis unit 1 is a CP that controls the control diagnosis unit.
U11, a diagnostic operation control unit 12 that issues a diagnostic operation command to the elevator to diagnose an abnormality in the elevator, and diagnostic data used to predict an elevator failure during the diagnostic operation. Part 1
3, a sign determination unit 14 that predicts a failure based on the diagnostic data collected by the data collection unit 13, and a storage unit 15 that stores the result of the sign of the failure by the sign determination unit 14 as sign data described later. And a communication device 16 for communicating the sign data stored in the storage unit 15 to the diagnostic center 2. The diagnostic center 2 also stores a CPU 21 that controls the diagnostic center 2, a predictive data storage unit 22 that stores predictive data from the control diagnostic unit 1, and data such as the customer name of the elevator to which the predictive data is sent. A customer data storage unit 23, and a maintenance work instruction storage unit 24 in which maintenance work instructions are stored for each sign data,
Work instruction sheet issuance determination unit 25 that determines whether or not to issue a work instruction sheet, input unit 26 that inputs conditions for prohibition and permission of work instruction sheet issuance, and work instruction sheet data that is communicated to sales office 3. Of the sign data sent from each diagnostic center, having a storage unit 27 for temporarily storing the data, a communication device 27 for communicating with the control diagnosis unit 1, and a communication device value 28 for communicating with the sales office 3. It constitutes a means for transmitting predictive work instruction information for each content to the sales office. Further, the sales office 3 controls the CPU 31 for issuing a work instruction, and the input unit 32 for setting an instruction issue date and a periodic maintenance date.
A storage unit 33 for temporarily storing the work instruction data sent from the diagnostic center 2, a printing device 34 for printing the work instruction, and a communication device 35 for communicating with the diagnostic center 2.
And the output means for outputting the predictive work instruction sheet based on the predictive work instruction information sent from the diagnostic center.

FIG. 2 is a flow chart showing the flow of operation of the diagnostic control unit 1. When the diagnostic control unit 1 starts operating, the diagnostic operation control unit 12 gives a diagnostic operation command to the elevator control device in step S10. As a result, the elevator will switch from normal operation to diagnostic operation from the bottom floor to the top floor if certain conditions are satisfied, such as no passengers in the car or the car call button is not registered. Stop operation is performed on each floor to measure the landing position on each floor, measure the starting vibration of the car at the departure of each floor, and measure acceleration / deceleration. Further, after the stop operation on each floor is completed, the operation is switched to low speed operation, and the limit switches set on the hoistway on the lowest floor and the top floor are operated to measure the operating position. At this time, the measurement values are collected by the data collection unit 13, and data such as measurement time and measurement floor are added,
In step S20, it is stored in the storage unit 15 as diagnostic data.

Next, at step S30, the sign determination unit 14 compares the collected diagnostic data with the failure sign determination value, and if the result of the comparison is that the diagnostic data exceeds the predetermined sign determination value, the sign determination is made. Section 14 determines that the elevator will fail in the future. In addition, the sign determination unit 14 performs step S4.
At 0, the characteristic of the temporal change of the diagnostic data reaching the sign judgment value, for example, the temporal change of the frequency or amplitude value or the change of the diagnostic data with respect to the number of operations is extracted, and step S50
In step S6, the abnormal device is identified by comparing with the abnormal progress characteristic data of the device that the sign determination unit 14 has.
A failure occurrence date in which a failure occurs in the elevator is predicted as 0, and those results are stored in the storage unit 15 as predictor data in step S70. In addition, it is possible to predict failure occurrence not only by the date of occurrence but also by the number of operations and time, and the predictive data is abnormal car start vibration, acceleration / deceleration error, landing level error, floor-specific doors. Abnormality, limit switch operation abnormality, floor-specific push button abnormality data, etc.
It is composed of an abnormality occurrence date, an abnormality occurrence frequency, an abnormality occurrence floor, diagnostic data, a predicted failure occurrence date, and the like.

Next, in step S80, the CPU 11 determines whether the sign data stored in the storage unit 15 satisfies a predetermined condition set in advance. If the condition is satisfied, the communication device 16 in step S90. Predictive data is communicated to the diagnostic center 2 through the. The preset predetermined condition for transmitting the sign data to the diagnostic center 2 is defined for each abnormality detection content. For example, in the case of an abnormal landing level, the error of the current landing level is 15 mm and this landing level error is 15 mm. If the predicted failure occurrence date when the floor level error is 30 mm is within 1 day, the predictive data is immediately transmitted to the diagnostic center 2. However, if the predicted failure occurrence date is 1 month or more, the diagnostic center 2 immediately before the regular maintenance day. The conditions are set so that the predictive data is transmitted in response to the request of. If it is determined that the predicted failure date is imminent, the predictive data is immediately communicated to the diagnostic center in step S90, and maintenance / repair measures are taken as quickly as possible to prevent a user's trip or other injury. To prevent. However, if the predicted failure date is more than one month, the predictive data should be communicated according to the request of the diagnostic center 2 immediately before the regular maintenance day to be performed once or twice a month, and the corrective action should be taken on the regular maintenance day. By doing so, it is possible to prevent breakdowns and reduce the number of non-periodical dispatch of maintenance personnel. As described above, the condition of communication to the diagnostic center 2 is determined by the contents of the predictive data.

As described above, the diagnostic control unit 1 not only detects the abnormality of the elevator but also identifies the abnormal equipment and predicts the date of occurrence of the failure. No need to collect anomalous data,
The line cost and data collection time can be greatly reduced, and the load on the computer for failure diagnosis at the diagnostic center can be reduced. Also, depending on the details of the anomaly in the sign data and the date of the predicted failure,
Since the symptom data is communicated to the diagnostic center 2 to prompt the maintenance work, it is possible to prevent the delay of the maintenance, and also to reduce the communication load on the telephone line of the diagnostic center 3 and to prevent the maintenance staff from performing irregular maintenance. It is possible to reduce dispatch.

Next, as an example of a failure sign of an elevator,
For example, a failure sign due to an abnormality in the anti-vibration rubber of the car floor will be described. Among the diagnostic data collected by the data collection unit 13, the diagnostic data of the starting vibration of the car was 0.005 m / min ² at the beginning of the operation of the elevator.
If the starting vibration reaches 0.041 m / min ^{2 in the} 12th month, the sign determining unit 14 determines in step S30 that the diagnostic data of the starting vibration of the car is 0.040 m / min which is the sign determining value.
Detecting that min ² is exceeded, it is determined that a failure will occur in the elevator in the future. Next, the sign determination unit 14 calculates in step S40 what kind of temporal transition change the starting vibration of the car has taken up to now, and as a result, the starting vibration value of the car is 0 every month after the start of operation. .003m
When the characteristic of the abnormality and the speed of progress of the abnormality are calculated for each / min ² , the sign determination unit 14 compares the abnormal progression characteristic data of the device included in the sign determination unit 14 with the characteristic calculation result of the diagnostic data in step S50. However, the device with abnormal starting vibration value of the car is specified as the anti-vibration rubber installed on the car floor. The sign determination unit 14 also determines in step S60.
Predict the number of days until an elevator failure occurs.
For example, here, the diagnostic data of the starting vibration from the beginning of the operation of the elevator is 0.003 m / min ² per month.
It is predicted that it will take three months to reach the starting vibration value of the elevator car 0.049 m / min ^{2 in} which the elevator is out of order. The result of this sign is stored in the storage unit 15 as sign data in step S70. For example, Elevator serial number: 1123, Abnormality content: Abnormal car start vibration value, Abnormality occurrence date: 1993
March 31, 2012, Number of occurrences: 1, Occurrence floor: 1st floor, Diagnostic data: 0.041 m / min ² , Predicted failure occurrence date: 1
I remember that it was June 31, 993.

Here, the abnormal progression characteristic data of the device is
For example, in the characteristic data of abnormal progress of anti-vibration rubber on the floor of a car, for about a year from the start of operation, the car contracts in proportion to the time due to the weight of the car. The starting vibration value of the car also increases in proportion to the time, and the hardness and elasticity of the car are kept stable for about seven years thereafter. Therefore, the starting vibration value of the car does not change with time. After that, the anti-vibration rubber on the floor of the car hardens and loses elasticity, and the bending cannot be restored even when all the passengers in the car are present, so the elevator cannot correctly detect the passengers in the car. During the operation of the elevator for one day, there is a large difference between the maximum value and the minimum value of the starting vibration value of the car. The abnormal progress characteristic data of the device is data obtained by converting the characteristic of the abnormal progress of the device. Further, the abnormal progress characteristic data of the device contains data on the extent of the abnormal progress with respect to time and the number of operations for each device. Here, the abnormal progression characteristics of the car floor anti-vibration rubber are described as the abnormal progression characteristic data of the equipment.However, the abnormal progression characteristic data of the equipment is converted into data of all the abnormal progression characteristics of the elevator component equipment. Remembered. Then, in step S80, C
The PU 11 refers to the predictive failure occurrence date: June 31, 1993 of the predictive data stored in the storage unit 15 and determines whether to communicate the predictive data in the diagnostic center 2.
The CPU 11 determines that there is no need to immediately communicate the predictive data because it takes three months before the failure occurs, and communicates the predictive data in response to the communication request from the diagnostic center 3 immediately before the regular maintenance day.

Next, the processing of the diagnostic center 2 will be described. Immediately before the scheduled maintenance date stored in the customer data storage unit 23, the diagnostic data requested by the diagnostic control unit 2 to the diagnostic control unit 1 and communicated, or the diagnostic control unit 1 predicts separately from the request of the diagnostic center 2. When the diagnostic center 2 receives, through the communication device 27, the respective predictor data of the plurality of elevators that have communicated with each other because it is determined that the failure date is imminent.
The CPU 21 temporarily stores the predictive data in the predictive data storage unit 22, and rearranges the stored predictive data of each elevator in order of the predicted failure occurrence date closest to the present. Next, the CPU 21 reads the predictor data from the predictor data storage unit 22 in order from the beginning of the rearranged predictor data, and sends the predictor data to the work instruction sheet issue determination unit 25. The work instruction issuance determination unit 25 determines whether or not the abnormality content of the sent predictor data may be issued to the sales office as a work instruction, and if the issuance is prohibited, it is the sign data. If it is determined that the work instruction document issuance determination unit 25 C
The process is transferred to the PU 21, and the next sign data stored in the sign data storage unit 22 is processed. If it is determined that the issuance is not prohibited sign data, the work order issuance determination unit 25 uses the elevator manufacturing number in the sign data and uses the customer data necessary for the work order issued to the sales office 3. Is extracted from the customer data storage unit 23 and stored in the storage unit 27. Further, the work instruction sheet issuance determination unit 25 indicates the date of occurrence of the abnormality in the sign data, the number of occurrences, the floor at which the abnormality occurred, and the diagnostic data. Using the predicted failure occurrence date and the predicted number of operations of the device,
The storage unit 27 stores the contents of the work instruction for each sign data necessary for the work instruction output to the business office 3 stored in the work data storage unit for each sign data 24. Next, the work instruction book issue determination unit 25 communicates the data stored in the storage unit 27 to the communication device 35 of the sales office 3 via the communication device 28. When this communication is completed, the sign data stored in the sign data storage unit 22 is erased. Input unit 26 of diagnostic center 2
Is for inputting to the work instruction issuance determination unit 25 a prohibition condition or cancellation of prohibition of issuance of the work instruction of the predictive data,
For example, as a condition for prohibiting the issuance of work instructions, the name of an abnormality such as a car start vibration abnormality is specified among various predictor data to prohibit the issuance of work instructions, or the elevator serial number is specified. And prohibit issuing work instructions.

Next, the process of issuing a work instruction at the business office 3 will be described. The CPU 31 receives the data communicated from the storage unit 27 of the diagnostic center 2 with the communication device 35 and stores the data in the storage unit 33. Next, the CPU 31 uses the storage unit 2
The data stored in 7 is used to create a work instruction sheet by the output means such as the printing device 34. The input unit 32 inputs customer information such as a customer name of each elevator, a scheduled maintenance date, a work instruction sheet print designation date, and the like, and the entered customer information is communicated to the diagnostic center 2 by the communication device 35 to perform diagnosis. It is stored in the customer data storage unit 23 of the center 2.

As described above, in this embodiment, the failure occurrence of the elevator is predicted by the diagnosis control unit 1 and the predicted failure occurrence date is output to the sales office 3. Therefore, the information collected by the diagnosis center 2 is reduced as compared with the conventional case. As a result, it is possible to prevent the trouble that the notification is concentrated on the limited telephone line of the diagnostic center 2 and the telephone line is difficult to connect. Moreover, the maintenance work is delayed and the elevator is broken even though the abnormality is detected in advance. It is possible to reliably prevent the problem of causing it. still,
Regarding the timing of outputting the predicted failure occurrence date to Sales Office 3,
The present invention is not limited to the above-mentioned embodiment, and can be arbitrarily selected.

[0018]

As described above, in the elevator failure sign system of the present invention, the diagnostic control unit connected to the elevator control device detects the abnormality of the elevator, identifies the abnormal equipment, and predicts the failure date. As a result, it is possible to reduce the load on the diagnostic staff of the diagnostic center and the diagnostics of the computer, and to eliminate the need to communicate a large amount of diagnostic data necessary for diagnostics to the diagnostic center. Maintenance work can be performed without

[Brief description of drawings]

FIG. 1 is a block diagram of an elevator failure sign system according to an embodiment of the present invention.

FIG. 2 is a flowchart showing an operation of a diagnosis control unit shown in FIG.

[Explanation of symbols]

 1 Control Diagnosis Section 2 Diagnostic Center 3 Sales Office 14 Prediction Judgment Section 24 Prediction Data-Specific Work Instruction Storage Section 25 Work Instruction Issuance Judgment Section

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Yuichi Hara, 1-6 Kandanishikicho, Chiyoda-ku, Tokyo Within Hitachi Building System Service Co., Ltd. (72) Takaaki Oka 1-6, Kandanishikicho, Chiyoda-ku, Tokyo Shares Inside the Hitachi Building System Service

Claims (1)

[Claims] 1. An elevator failure signage system in which a plurality of elevator control diagnosis units and business offices are connected by a diagnosis center, wherein each of the control diagnosis units includes a data collection unit that collects diagnosis data during operation of the elevator. A sign determination unit that detects an abnormality based on the diagnostic data, predicts an abnormal device identification and a failure occurrence date, and means that transmits the sign data from the sign determination unit to the diagnostic center, The diagnostic center includes means for transmitting predictive work instruction information for each content of the predictive data sent from each diagnostic center to the sales office, and the sales office
An elevator failure sign system comprising an output means for outputting a sign work instruction sheet based on the sign work instruction information sent from the diagnostic center.