KR20200051758A - Data processing apparatus, data processing system, data processing method, data processing program and storage medium - Google Patents

Abstract

The data processing apparatus 2 includes an algorithm selection unit 26 and a life prediction processing unit. The algorithm selection unit 26 uses an algorithm storage unit 30 in which an algorithm for predicting the life of components constituting the device is stored, and an algorithm corresponding to the target component that is the target of life prediction among the components constituting the apparatus. Choose. The preventive maintenance processing unit 25, which is the life prediction processing unit, executes the life prediction processing of the target part based on the algorithm selected by the algorithm selection unit 26.

Description

Data processing apparatus, data processing system, data processing method, data processing program and storage medium

The present invention relates to a data processing apparatus, a data processing system, a data processing method, a data processing program and a storage medium that perform data processing for preventive maintenance of the apparatus.

Preventive maintenance that prevents failures occurring in the device by monitoring the signs of failures based on the data obtained by measuring the condition of the devices and predicting the remaining life until the level of these signs exceeds a certain reference level. The method of is known.

Patent Document 1 discloses a control system that predicts the life of each part based on information from sensors provided in a plurality of parts constituting the engine, and predicts the life of the entire engine from the life of each part. The control system of Patent Document 1 predicts the trend of a phenomenon that is a cause of failure such as crushing or loss of coating, and determines the remaining life of the component from the prediction result of the occurrence rate of the failure due to the occurrence of this phenomenon. The control system of patent document 1 is programmed to calculate the remaining life of a component according to a life prediction algorithm using data on the operating state of the engine.

Patent Document 1: Japanese Patent Publication No. 2014-518974

At the production site of the product, in order to enable a planned and stable production, preventive maintenance of a production device operated at the production site is required. By calculating the life of each component constituting the production device by using an algorithm that estimates the life of the production device based on the data obtained by actually measuring the state of the production device, the user of the production device is informed of when to perform maintenance or replacement of parts. Can be.

Generally, the components constituting the production device are arbitrarily selected by the manufacturer of the production device. When the technology of Patent Document 1 is applied to a production device, the provider of the application for preventive maintenance included in the production device constructs an algorithm specialized for the configuration of the production device for each manufacturer of the production device. Moreover, even when there are additions or replacements of parts in the production apparatus, the algorithm is rebuilt again. Therefore, according to the technique of patent document 1, there exists a problem that the burden required for construction of the application used for data processing for preventive maintenance of an apparatus may increase.

The present invention has been made in view of the above, and an object of the present invention is to obtain a data processing device that can reduce the burden required for the construction of an application used for data processing for preventive maintenance of a device.

In order to solve the above-described problems and achieve the object, the data processing apparatus according to the present invention predicts the life of the components constituting the apparatus from an algorithm storage unit storing an algorithm for predicting the life of the components constituting the apparatus It is characterized in that it comprises an algorithm selection unit for selecting an algorithm corresponding to the target component to be targeted, and a life prediction processing unit for performing the life prediction processing of the target component based on the algorithm selected by the algorithm selection unit.

The data processing apparatus according to the present invention achieves an effect that the burden required for the construction of an application used for data processing for preventive maintenance of the apparatus can be reduced.

1 is a block diagram of a data processing system according to Embodiment 1 of the present invention.
FIG. 2 is a configuration diagram of a preventive maintenance application installed in the data processing device shown in FIG. 1.
FIG. 3 is a block diagram showing the functional configuration of the data processing device shown in FIG. 1.
FIG. 4 is a block diagram showing the hardware configuration of the data processing device shown in FIG. 1.
5 is a flowchart showing a procedure of processing by the task handler shown in FIG. 2.
6 is a block diagram showing the functional configuration of the preventive maintenance processing unit shown in FIG. 3.
7 is a diagram showing a representative life curve and a failure threshold value selected by the representative life curve selector shown in FIG. 6.
FIG. 8 is a first diagram illustrating generation of a life prediction curve by the life prediction curve generator shown in FIG. 6.
FIG. 9 is a second diagram illustrating generation of a life prediction curve by the life prediction curve generation unit shown in FIG. 6.
FIG. 10 is a third diagram illustrating generation of a life prediction curve by the life prediction curve generation unit shown in FIG. 6.
FIG. 11 is a fourth diagram illustrating generation of a life prediction curve by the life prediction curve generation unit shown in FIG. 6.
12 is a flow chart showing a procedure of processing by the data processing apparatus after the preventive maintenance algorithm shown in FIG. 2 is selected.
13 is a flow chart showing a procedure of a process for generating a life prediction curve by the life prediction curve generation unit shown in FIG. 6.

Hereinafter, a data processing apparatus, a data processing system, a data processing method, a data processing program and a storage medium according to an embodiment of the present invention will be described in detail based on the drawings. In addition, this invention is not limited by this embodiment.

Embodiment 1.

1 is a block diagram of a data processing system according to Embodiment 1 of the present invention. The data processing system 1 shown in FIG. 1 has a data processing apparatus 2, a device 4A connected to the data processing apparatus 2, and devices 4B, 4C connected to the device 4A. The devices 4A, 4B, and 4C are devices for acquiring industrial data. Industrial data is data such as temperature, voltage, current, distance, speed, or location information, and is all data on the state of a production device or a production site.

The device 4B is a production device, and is a driving device such as a numerical control (NC) device, a servo motor, and an inverter. The device 4A is a controller that controls the device 4B, and is a programmable logic controller (PLC). The device 4C is a sensor mounted on the device 4B which is a production device, and is a vibration sensor, a collecting microphone, a current clamp meter, a temperature sensor, and the like. The number of devices 4A, 4B, and 4C provided in the data processing system 1 is assumed to be arbitrary. The data processing system 1 shown in Fig. 1 includes one device 4A, two devices 4B, and one device 4C. The devices 4A, 4B, and 4C are not limited to the specific examples described above, and may be devices that acquire industrial data.

The data processing apparatus 2 is a computer in which the preventive maintenance application 10 which is a data processing program is installed. The data processing apparatus 2 collects the industrial data transmitted from the devices 4A, 4B, 4C, and performs a series of functional processing on the industrial data. The function processing performed in the data processing apparatus 2 includes processing for predicting the life of components constituting the device 4B. The data processing apparatus 2 is connected to the cloud server 3 which is an external server. The display device 5 is connected to the data processing device 2. The display device 5 displays the result of the life prediction obtained by the data processing device 2.

The device 4B is provided with a mechanism for transmitting the driving force of the motor. One of the main causes of the failure of the device 4B is the abnormality of the rotating mechanism that rotates under the driving force of the motor. In the first embodiment, the data processing apparatus 2 prevents and maintains the device 4B by predicting the life of at least one of bearings, ball screws, gears, and belts, which are the main components constituting the rotating mechanism. In addition, in FIG. 1, illustration of a motor, an operation mechanism, a rotation mechanism, and components is omitted.

FIG. 2 is a configuration diagram of the preventive maintenance application 10 installed in the data processing device 2 shown in FIG. 1. The data processing program preventive maintenance application 10 includes a task handler 11 and a preventive maintenance algorithm 12. The preventive maintenance algorithm 12 is a program that implements an algorithm for preventive maintenance and implements the mounted algorithm. In addition, the preventive maintenance algorithm 12 may be information in which a calculation procedure for preventive maintenance is described in place of the program. The information in which the calculation procedure is described may include information indicating the calculation formula. In this case, the algorithm for preventive maintenance is realized by the preventive maintenance application 10 referring to the stored preventive maintenance algorithm 12. In the following description, it is assumed that the preventive maintenance algorithm 12 is a program.

The preventive maintenance algorithm 12 is prepared for each type of component. In the first embodiment, at least four preventive maintenance algorithms 12 for bearings, ball screws, gears, and belts are used. The preventive maintenance algorithm 12 for each of the more detailed component types, such as for large bearings, medium bearings, and small bearings, may be used. The data processing device 2 can predict the lifespan reflecting the influence of product specifications, such as differences in dimensions for each part, by referring to the specification parameter 15 described later. For example, when life prediction is performed for bearings having different dimensions, it is assumed that a common algorithm corresponding to both bearings is used, and the specification parameters 15 may be different.

The user of the device 4B downloads the preventive maintenance application 10 including the preventive maintenance algorithm 12 from a store or the like selling the application on a website, and installs it on the data processing apparatus 2. The user of the device 4B can change the preventive maintenance algorithm 12 included in the preventive maintenance application 10. The user of the device 4B further acquires the preventive maintenance algorithm 12 by downloading from a store or the like selling the application on the website. The user of the device 4B may acquire the preventive maintenance algorithm 12 by reading the preventive maintenance algorithm 12 from a storage medium in which the preventive maintenance algorithm 12 is stored. The user of the device 4B may acquire the preventive maintenance application 10 by reading the preventive maintenance application 10 from a storage medium in which the preventive maintenance application 10 is stored. The user of the device 4B can configure the preventive maintenance application 10 by arbitrarily combining the preventive maintenance algorithm 12.

The provider of the preventive maintenance application 10 provides the user of the device 4B with a preventive maintenance application 10 that can add and replace the preventive maintenance algorithm 12. The task handler 11 is provided as standard in the preventive maintenance application 10 provided by the provider of the preventive maintenance application 10. The provider of the preventive maintenance algorithm 12 is assumed to be the manufacturer of the component, the manufacturer of the device 4B, or the provider of the preventive maintenance application 10, but may be any other person.

The task handler 11 reads setting information 14 and specification parameters 15. The setting information 14 includes identification information for identification of the preventive maintenance algorithm 12 for each part, identification information for identification of the specification parameter 15 for each part, and information for specifying a part for performing life prediction. , It is a file containing information on the life cycle of the life prediction for each component that performs life prediction. Among the parts included in the preventive maintenance application 10, the user of the device 4B can set which component to perform the life prediction for. Among the plurality of preventive maintenance algorithms 12 included in the preventive maintenance application 10, the preventive maintenance algorithm 12 to be used may be arbitrarily selected by the user.

The specification parameter 15 is a file defining part-specific information. The specification parameter 15 is referenced at the time of specifying the component-specific failure mode. The specification parameter 15 includes information such as dimensions of parts. For a specific example, the specification parameters 15 for the bearings include the diameter of the rolling element, the pitch circle diameter of the rolling element, the number of rolling elements, and the numerical values of the contact angle. It is assumed that the user of the device 4B can obtain specification parameters 15 created for each manufacturer of parts and for each type of product through the web or a storage medium. The specification parameter 15 is prepared by the manufacturer of the part, but may be created by other people.

The identification information of the preventive maintenance algorithm 12 is a file name given to the file of the preventive maintenance algorithm 12. The identification information of the specification parameter 15 is a file name assigned to the file of the specification parameter 15. The identification information of the preventive maintenance algorithm 12 may be information that can identify the preventive maintenance algorithm 12 for each part, and may be information other than the file name. The identification information of the specification parameter 15 may be information that can identify the specification parameter 15 for each part, and may be information other than the file name.

The task handler 11 manages the processing of the preventive maintenance in the preventive maintenance application 10. The management of the preventive maintenance processing by the task handler 11 includes management of the execution cycle of life prediction for each component. The task handler 11 recognizes the execution cycle of each component based on the information of the execution cycle included in the setting information 14. The data processing apparatus 2 can perform life prediction at independent timing for each component constituting the device 4B by managing the execution cycle in the task handler 11.

The task handler 11 executes life prediction for the part when there is a part whose execution cycle has arrived. In addition, information indicating that life prediction is not performed may be set in the information of the execution cycle. When information indicating that the life prediction is not performed is set, the task handler 11 may also not perform the life prediction for parts corresponding to the setting. The data processing device 2 executes the preventive maintenance algorithm 12 corresponding to some of the components included in the preventive maintenance application 10, and the corresponding preventive maintenance algorithm 12 corresponds to other components The preventive maintenance algorithm 12 described above may not be executed. The task handler 11 activates a thread 13 for executing processing for the target component, which is the target of life prediction. The thread 13 selects the preventive maintenance algorithm 12 corresponding to the target part based on the identification information included in the setting information 14 for the target part.

The thread 13 executes processing according to the selected preventive maintenance algorithm 12 using the specification parameter 15 of the corresponding target part. The task handler 11 performs parallel processing by a plurality of threads 13 when there are a plurality of parts whose execution cycle has arrived. The thread 13 executes a process according to the preventive maintenance algorithm 12 using the specification parameter 15, thereby executing the life prediction process. The functions of the preventive maintenance algorithm 12 include each function of calculating the failure frequency, calculating the measured value, specifying the failure mode, selecting the representative life curve, selecting the life prediction curve, and calculating the predicted life. Each function of the preventive maintenance algorithm 12, the failure frequency, and the failure mode will be described later.

3 is a block diagram showing the functional configuration of the data processing apparatus 2 shown in FIG. 1. Each functional unit shown in FIG. 3 is realized by executing the preventive maintenance application 10 on a computer that is hardware.

The data processing device 2 includes a control unit 20 that is a function unit that controls the data processing device 2, a storage unit 21 that stores information, and a communication unit 22 that is a function unit that communicates information, and information. It has an input unit 23 which is a function unit for inputting.

The control unit 20 includes a preventive maintenance management unit 24 which is a function unit for managing the processing of preventive maintenance. The preventive maintenance management unit 24, which is an execution cycle management unit, manages the execution cycle of life prediction. In addition, the control unit 20, from the preventive maintenance processing unit 25, which is a function unit that performs the life prediction processing, and the preventive maintenance algorithm 12 for each component, includes the components constituting the device, which are targeted for life prediction. An algorithm selection unit 26, which is a function unit for selecting the corresponding preventive maintenance algorithm 12, is provided. The preventive maintenance processing unit 25 is a life prediction processing unit that executes the process of predicting the life of the target part based on the algorithm selected by the algorithm selection unit 26. The function of the preventive maintenance management unit 24 and the function of the algorithm selection unit 26 are realized by the processing of the task handler 11. The function of the preventive maintenance processing unit 25 is realized by the processing of the preventive maintenance algorithm 12 executed by using the specification parameter 15 of the target component.

The storage section 21 is an algorithm storage section 30 for storing the preventive maintenance algorithm 12, and an industrial data storage section 31 for storing industrial data for all parts obtained from the devices 4A, 4B, 4C. And a specification parameter storage unit 32 for storing the specification parameters 15 of the parts.

The preventive maintenance algorithm 12 included in the preventive maintenance application 10 is stored in the algorithm storage unit 30. The industrial data storage unit 31 stores industrial data acquired at intervals of 1 second together with time information. The industrial data storage unit 31 may store industrial data acquired at intervals of millisecond orders or microsecond orders, or may store industrial data acquired at other intervals. As a specific example, the industrial data acquired by the device 4B for the bearing includes respective values of motor current, encoder position, motor speed, and temperature. The preventive maintenance processing unit 25 calculates the vibration frequency of the bearing based on the industrial data for the bearing. The calculation of the vibration frequency will be described later. The industrial data acquired by the device 4C, which is a sensor provided in the bearing, includes respective values of vibration acceleration and sound pressure level. The specification parameter storage 32 stores specification parameters 15 for each component of the device 4B.

Further, the storage unit 21 includes a life data storage unit 33 that stores the results of life prediction by the preventive maintenance processing unit 25, and a representative life curve storage unit 34 that stores a representative life curve and a failure threshold. , A setting information storage unit 35 for storing setting information 14 is provided. Specifically, the life data storage unit 33 stores a failure mode for each part, the remaining life of the parts, and an identification score. The setting information 14 is input to the data processing apparatus 2 by the manufacturer of the device 4B. Representative life curves, failure thresholds, failure modes, and identification scores are described below.

The communication unit 22 communicates between the data processing device 2 and devices 4A, 4B, and 4C, which are devices other than the data processing device 2, the display device 5, and the cloud server 3. The input unit 23 inputs setting information 14 to the data processing device 2.

4 is a block diagram showing the hardware configuration of the data processing device 2 shown in FIG. 1. The data processing device 2 includes a central processing unit (CPU) 40 that performs various processes, a random access memory (RAM) 41 including a program storage area and a data storage area, and A hard disk drive (HDD) 42, which is an external storage device, is provided. Moreover, the data processing apparatus 2 is provided with the communication circuit 43 which is a connection interface with the external apparatus of the data processing apparatus 2, and the input device 44 which accepts input operation to the data processing apparatus 2. do. Each part of the data processing apparatus 2 shown in FIG. 4 is connected to each other via the bus 45. Incidentally, the external memory device may be a semiconductor memory.

The HDD 42 stores the preventive maintenance application 10, industry data, specification parameters 15 of parts, life data as a result of life prediction, a representative life curve, and setting information 14. The function of the storage unit 21 shown in Fig. 3 is realized using the HDD 42.

The preventive maintenance application 10 is loaded into the RAM 41. The CPU 40 deploys the preventive maintenance application 10 in the program storage area in the RAM 41 to execute various processes. The data storage area in the RAM 41 serves as a work area in executing various processes. The function of the control unit 20 shown in FIG. 3 is realized using the CPU 40. The function of the communication unit 22 is realized using the communication circuit 43. The input device 44 includes a keyboard or pointing device. The function of the input unit 23 shown in FIG. 3 is realized using the input device 44.

In addition, the preventive maintenance application 10 may be stored in a storage medium capable of being read by a computer. The data processing device 2 may store the preventive maintenance application 10 stored in the storage medium in the HDD 42. The storage medium may be a removable storage medium that is a flexible disk or a flash memory that is a semiconductor memory. The preventive maintenance application 10 may be installed in the data processing device 2 from another computer or server device through a communication network.

5 is a flowchart showing a procedure of processing by the task handler 11 shown in FIG. 2. The task handler 11 starts in response to the start of the computer, which is the data processing device 2, and maintains the start state until the computer is shut down.

In step S1, the task handler 11 determines whether or not there is a component whose execution cycle of the life prediction has arrived, based on the information of the execution cycle included in the setting information 14 read from the setting information storage unit 35. do. When there are no parts whose execution cycle has arrived (steps S1 and No), in step S2, the task handler 11 waits until the next determination of the presence or absence of the parts whose execution cycle has arrived. After waiting in step S2, the task handler 11 returns the processing to step S1.

When there is a component whose execution cycle has arrived (step S1, Yes), the task handler 11 starts the thread 13 for the target component which is the component whose execution cycle has arrived in step S3. In step S4, the thread 13 selects the preventive maintenance algorithm 12 of the target part based on the identification information included in the setting information 14 for the target part. Thereby, the task handler 11 selects the preventive maintenance algorithm 12 of the target component from the preventive maintenance algorithms 12 stored in the algorithm storage unit 30. In addition, the task handler 11 is not limited to executing the process of step S3 when there is a component whose life cycle of execution of life prediction has arrived in step S1. The task handler 11 may execute the process of step S3 when the instruction to execute the preventive maintenance process is input from the input unit 23 by the user.

Based on the identification information of the specification parameter 15, the thread 13 selects a specification parameter 15 for the component to be predicted for life from among the specification parameters 15 read from the specification parameter storage 32. . In step S5, the thread 13 inputs the specification parameter 15 of the component to the preventive maintenance algorithm 12. In step S6, in the thread 13, the preventive maintenance algorithm 12 executes a life prediction process that is a preventive maintenance process. Upon completion of the processing in step S6, the task handler 11 ends the processing shown in FIG. 5.

6 is a block diagram showing a functional configuration of the preventive maintenance processing unit 25 shown in FIG. 3. The preventive maintenance processing unit 25 selects an actual value calculation unit 51 which is a function unit for calculating an actual value, a failure mode calculation unit 52 which is a functional unit for calculating a failure mode value for each failure mode, and a representative life curve. It includes a representative life curve selection unit 53 as a function unit, a failure mode specifying unit 54 as a function unit for specifying a failure mode, and a life prediction curve generation unit 55 as a function unit for generating a life prediction curve. Further, the preventive maintenance processing unit 25 includes a life prediction unit 56 which is a function unit for calculating the predicted life of the target component based on the preventive maintenance algorithm 12 selected by the algorithm selection unit 26.

The failure mode indicates the cause of the component failure. The failure mode value is a value used to specify the failure mode. The preventive maintenance algorithm 12 stored in the algorithm storage unit 30 includes a failure model that is a formula for calculating a failure mode value for each failure mode of a component. In the first embodiment, the failure mode is a cause of failure that can monitor the sign of the failure by observing the frequency of vibrations occurring in the part. The failure mode calculation unit 52 calculates a failure frequency that is a failure mode value. The failure frequency is a frequency of vibration that is a sign of a failure, and is a frequency unique to each failure mode. The failure mode calculation unit 52 calculates a failure frequency for each failure mode.

Here, the calculation of the failure frequency by the failure mode calculation unit 52 will be described using the bearing as one example as an example. The failure of the bearing can be caused by abnormalities in the inner ring, outer ring, retainer, and rolling elements. In the failure mode of the bearing, there are first to fifth failure modes described below.

In addition, in the formulas (1) to (5) shown below, "d" is the diameter of the rolling element, "D" is the diameter of the pitch circle of the rolling element, "Z" is the number of rolling elements, and "α". Is called the contact angle. The units of "d" and "D" are millimeters, and the units of "α" are radians. The failure mode calculating unit 52 acquires each value of "d", "D", "Z" and "α" from the specification parameter 15 read from the specification parameter storage unit 32. "F ₀ " is called the rotation frequency of the inner ring. The unit of "f ₀ " is in hertz. The failure mode calculation unit 52 calculates the value of "f ₀ " based on the industrial data 16 read from the industrial data storage unit 31.

In the first failure mode, as a defect of the retainer, a sign of the failure can be monitored by observing the rotation frequency f _m of the retainer. The failure mode calculation unit 52 calculates the rotation frequency f _m which is the failure frequency of the first failure mode by the following equation (1).

[Equation 1]

The second failure mode is a defect of the retainer, and it is possible to monitor the sign of the failure by observing the relative rotational frequency f _m-i of the retainer relative to the inner ring. The failure mode calculating unit 52 calculates the relative rotation frequency f _m-i , which is the failure frequency of the second failure mode, by the following equation (2).

[Equation 2]

The third failure mode is a scratch or peeling of the race surface of the inner ring, and it is possible to monitor the sign of the failure by observing the passing frequency f _i of the rolling element with respect to the inner ring. The failure mode calculation unit 52 calculates the pass frequency f _i which is the failure frequency of the third failure mode by the following equation (3).

[Equation 3]

The fourth failure mode is a scratch or peeling of the race surface of the outer ring, and it is possible to monitor the sign of the failure by observing the passing frequency f _O of the rolling element to the outer ring. The failure mode calculating unit 52 calculates the pass frequency f _O which is the failure frequency of the fourth failure mode by the following equation (4).

[Equation 4]

The fifth failure mode is a scratch or peeling of the rolling element, and the signs of the failure can be monitored by observing the rotating frequency f _b of the rolling element. The failure mode calculation unit 52 calculates the rotation frequency f _b which is the failure frequency of the fifth failure mode by the following equation (5).

[Equation 5]

When the target part is a bearing of a servo motor, the failure mode calculator 52 may calculate the rotation frequency f ₀ of the inner ring based on the speed monitor value, which is industrial data obtained from the servo motor. Alternatively, the failure mode calculator 52 may calculate the rotational frequency f ₀ of the inner ring based on the number of pulses that are industrial data obtained from the device 4C, which is a sensor provided in the external pulse encoder. The rotation frequency f ₀ is a value that fluctuates in a specific period. The failure mode calculation unit 52 acquires the rotation frequency f ₀ at a constant timing in the period.

By the rotation frequency f ₀ obtained in a certain timing, the value of the rotation frequency f ₀ obtained in the failure mode calculating unit 52 at each timing is constant. For this reason, the value of the rotation frequency f ₀ may be set as a value preset in the specification parameter 15 instead of a value calculated based on industry data. In addition, since even if the rotation frequency f ₀ obtained in a certain timing, since the case that the rotational frequency f ₀ marginally change by the device (4B) situations it, on the basis of the production data calculated rotation frequency f _0, It becomes possible to obtain a value that reflects a change in the situation of the device 4B more than a preset value. For this reason, by obtaining the rotation frequency f ₀ by calculation based on industrial data, the failure mode calculation unit 52 can calculate the failure frequency with high precision.

In addition, the failure mode may be a cause of failure that can monitor the signs of the failure by observing phenomena other than vibration. The failure mode calculating unit 52 may calculate a failure mode value other than the failure frequency. When the failure mode is a cause of failure that can monitor the sign of a failure by observing the temperature of the gearbox, the failure mode value is taken as the failure temperature, which is the temperature of the gearbox. The failure mode calculator 52 acquires the failure temperature.

The actual value calculation unit 51 reads the industrial data 16 stored in the industrial data storage unit 31, and calculates the actual value corresponding to the failure mode value based on the read industrial data 16. . When the failure mode value is the failure frequency, the actual value calculation unit 51 calculates the actual frequency that is the actual value. The measured frequency is a frequency of vibration occurring in the component, and is calculated based on the industrial data 16 obtained from the devices 4B and 4C. When the target component is a bearing, the actual value calculation unit 51 calculates the actual frequency based on the motor current value acquired by the device 4B. The measured value calculating unit 51 calculates the measured frequency by extracting the frequency component by a fast Fourier transform (FFT) of the motor current value. In addition, the industrial data storage section 31 stores data obtained by the FFT as industrial data 16.

When the vibration phenomenon is not observed in the device 4B, the actual value calculation unit 51 may calculate the actual frequency based on the industrial data 16 acquired by the device 4C. The vibration acceleration acquired by the vibration sensor which is the device 4C mounted on the bearing may be used for calculation of the actual frequency. The sound pressure level obtained by the sound pressure sensor which is the device 4C mounted on the bearing may be used for the calculation of the measured frequency. The actual value calculation unit 51 may calculate the actual frequency by extraction of frequency components by vibration acceleration or FFT of sound pressure level.

The failure mode specification unit 54 compares the failure mode value calculated by the failure mode calculation unit 52 with the actual value calculated by the measurement value calculation unit 51 to specify the failure mode of the target component. When the target component is a bearing, the failure mode specifying unit 54 determines a failure frequency that matches the actual frequency among the failure frequencies of the first to fifth failure modes. When the measured frequency coincides with the rotation frequency f _{m described} above, the failure mode specifying unit 54 specifies the failure mode of the bearing as the target component as the first failure mode.

The failure mode specifying unit 54 can apply various methods to the method of determining the coincidence or disagreement between the failure mode value and the measured value. The failure mode specifying unit 54 may determine whether the failure mode value and the measured value coincide based on a predetermined error range. The failure mode specifying unit 54 determines that the failure mode value and the measured value coincide when the difference between the failure mode value and the measured value is within an error range. The failure mode specification unit 54 sends information indicating the specified failure mode to the representative life curve selection unit 53 and the life prediction curve generation unit 55.

The failure mode specifying unit 54 may calculate an identification score indicating the accuracy of the phenomenon observed as a measured value corresponding to the failure mode value, which is a phenomenon caused by a failure in the specified failure mode. The failure mode specifying unit 54 calculates the identification score based on the difference between the failure mode value and the measured value. The identification score is sent to the life prediction unit 56 through the life prediction curve generation unit 55. The user of the device 4B can judge the reliability of the failure determination of the target component by referring to the identification score.

The representative life curve selection unit 53 selects a representative life curve and a failure threshold based on the failure mode specified by the failure mode specifying unit 54. The representative life curve, which is the first curve, is a curve that approximates data obtained by the accelerated life test of the part, and shows the relationship between the measured value and time corresponding to the failure mode value for the phenomenon occurring in the test. The life accelerated test is a test that intentionally proceeds with deterioration of a component under test to verify the life of the component. The failure threshold is the measured value when a component reaches a failure in the test.

FIG. 7 is a diagram showing a representative life curve C1 and a failure threshold T selected by the representative life curve selector 53 shown in FIG. 6. When the failure mode value is the failure frequency, the representative life curve C1 represents the relationship between the amplitude and the time of vibration generated in the test. The failure threshold T is the amplitude of vibration when the component reaches a failure in the test. That is, when the failure mode value is the failure frequency, the vibration amplitude corresponding to the failure frequency is plotted in time series. In Fig. 7, the vertical axis represents vibration amplitude, and the horizontal axis represents time. In the following description, the vertical axis representing the vibration amplitude may be referred to as the Y axis and the horizontal axis representing time may be referred to as the X axis. Incidentally, even if the parts are manufactured by the same manufacturer and are of the same type, there may be variations in the data obtained by the accelerated life test. The representative life curve C1 is a life curve representative of a life curve manufactured by the same manufacturer and obtained by parts of the same type.

The representative life curve curve storage section 34, which is a curve storage section, stores representative life cycle curves and failure threshold values for each failure mode for each component of the device 4B. The representative life curve selection unit 53 selects the representative life curve C1 and the failure threshold T corresponding to the target component and the specified failure mode from the representative life curve and failure threshold value stored in the representative life curve storage unit 34. . The time L1 is the time when the vibration amplitude reaches the failure threshold T in the representative life curve C1.

The representative life curve selection unit 53 sends the selection results of the representative life curve C1 and the failure threshold T to the life prediction curve generation unit 55. In addition, the vertical axis when the representative life curve C1 is displayed may indicate, in addition to the vibration amplitude, parameters such as temperature or frictional force according to the failure mode value. In addition, the abscissa may represent the accumulated temperature, which is a parameter indicating the progress of deterioration of parts, in addition to time.

The life prediction curve generation unit 55 generates a life prediction curve based on the representative life curve C1 selected by the representative life curve selection unit 53. The life prediction curve represents the prediction of the time series change of the measured value later than when the life prediction is executed. When the failure mode value is the failure frequency, the life prediction curve represents the relationship between the vibration amplitude and time after the life prediction is executed.

8 is a first diagram illustrating generation of a life prediction curve by the life prediction curve generation unit 55 shown in FIG. 6. FIG. 9 is a second diagram illustrating generation of a life prediction curve by the life prediction curve generation unit 55 shown in FIG. 6. The life prediction curve generation unit 55 reads the representative life curve C1 and the failure threshold T from the representative life curve storage unit 34 according to the selection result by the representative life curve selection unit 53.

The plot of the representative life curve C1 obtained by the life acceleration test and the measured value has a different length of the time axis. The life prediction curve generation unit 55 extends the time axis up to time L1 of the representative life curve C1 to the time axis up to time L2, which is the rated life time corresponding to the actual use situation of the target part, and extends the representative life curve C1 in the horizontal axis direction. Order. Rated life is the life of using standard products.

In a specific example, the rated life when the ball bearing as the target part is a ball bearing is expressed as (C / P) ³ × 16667 / n. The rated life when the ball bearing as a target part is a roller bearing is expressed as (C / P) ^10/3 × 16667 / n. Here, "C" is the basic dynamic load rating, "P" is the equivalent load, and "n" is the rotation speed. The unit of "C" and "P" is Newton, and the unit of "n" is set to revolution per minute (rpm). The unit of rated life is hour.

About "P" which is an equivalent load, P = X _r × Fr + Y _a × Fa holds. Here, "X _r " is the radial coefficient, "Fr" is the radial load, "Y _a " is the axial coefficient, and "F _a " is the axial load. The unit of "Fr" and "Fa" is Newton. The life prediction curve generation unit 55 acquires each value of "C", "n", "X _r ", and "Y _a " from the specification parameter 15 read from the specification parameter storage unit 32. The life prediction curve generation unit 55 acquires each value of "Fr" and "Fa" from the setting profile. The setting profile is a file that defines information specific to the device 4B and the usage environment of the device 4B. In addition, the life prediction curve generating unit 55 determines whether the ball bearing is a ball bearing or a roller bearing based on a set profile. The life prediction curve generation unit 55 may calculate the time L2, which is the rated life, based on the specification parameter 15 and the setting profile.

The life prediction curve generator 55 generates a second curve, the rated curve C2, by modifying the representative life curve C1 based on the failure threshold T and the rated life time L2. The constants "a", "b", and "c" of the exponential function Y = a × b ^x + c represented by the rated curve C2 are in the X-axis direction until the vibration amplitude at time L2 coincides with the failure threshold T It is obtained by lengthening the representative life curve C1. The life prediction curve generation unit 55 increases the representative life curve C1 by lengthening the X axis among the X and Y axes.

FIG. 10 is a third diagram illustrating generation of a life prediction curve by the life prediction curve generation unit 55 shown in FIG. 6. The life prediction curve generation unit 55 reads the measured value of the vibration amplitude up to the present among the industrial data 16 from the industrial data storage unit 31 and plots the read measured value on the time axis up to the present. In the case where the target component is a bearing, the vibration amplitude can be extracted from the data obtained by FFTing the motor current value obtained by the device 4B by the measured value calculation unit 51. The life prediction curve generation unit 55 generates an actual curve C3 representing the exponential function Y = a ＇× b ^× + c＇ by approximation of the measured value. The life prediction curve generation unit 55 generates a measurement curve C3, which is a third curve indicating the relationship between the measured value of vibration amplitude and the time corresponding to the failure mode value. The constant "b" of the actual measurement curve C3 matches the constant "b" of the rated curve C2. The time L3 is taken as the time when the vibration amplitude reaches the failure threshold T in the actual measurement curve C3.

When the most recent measured value from the present is smaller than the most recent previous measured value, the constant "a" may be a negative value. In this case, the life prediction curve generation unit 55 may use the constant “a＇ ”calculated in the life prediction of the previous time to generate the actual measurement curve C3. Alternatively, if the previous constant "a" does not exist, the life prediction curve generation unit 55 may use the constant "a" of the representative life curve C1 to generate the actual measurement curve C3.

FIG. 11 is a fourth diagram illustrating generation of the life prediction curve C4 by the life prediction curve generation unit 55 shown in FIG. 6. The life prediction curve generation unit 55 generates a life prediction curve C4 by mixing the rated curve C2 and the measured curve C3. Thereby, the preventive maintenance processing part 25 obtains the life prediction curve C4 generated based on the rated curve C2 and the actual measurement curve C3. The life prediction curve generator 55 generates a life prediction curve C4 by applying a weight indicating the degree of control of the actual curve C3 in the life prediction curve C4 to the actual curve C3. As a result, the life prediction curve generation unit 55 changes the proportion of the actual measurement curve C3 included in the life prediction curve C4.

The life prediction curve generation unit 55 changes the weight ratio p used for generation of the life prediction curve C4 to 0% as the lower limit and 100% as the upper limit. When the weight ratio p is 0%, the life prediction curve C4 coincides with the rated curve C2. When the weight ratio p is 100%, the life prediction curve C4 coincides with the actual measurement curve C3. The time L4 is the time when the vibration amplitude reaches the failure threshold T in the life prediction curve C4.

Here, an example of setting the weight ratio p will be described. The weight ratio p is determined based on the condition of the vibration amplitude as the vertical axis and the time condition as the horizontal axis shown in FIG. 11. The vibration amplitude condition is the Y-axis condition, and the time condition is the X-axis condition.

In the first life prediction after starting the operation of the device 4B, the weight ratio p is set to 0% based on the X-axis condition called the first. Moreover, when the time from the start of the operation of the device 4B to the present time exceeds the time L2, which is the rated life of the target part, based on the X-axis condition that the time L2 has been exceeded, the weight ratio p is 100%. Shall be

When the measured value of the vibration amplitude in the current is constant with the measured value at the time of the previous life prediction, based on the Y-axis condition that the vibration amplitude is constant, the weight ratio p and the weight ratio p determined in the last life prediction Same thing. Incidentally, the fact that the two measured values are constant means that the difference between the two measured values is within a preset percentage range.

Based on the Y-axis condition that the vibration amplitude has increased when the actual measured value of the vibration amplitude is not constant from the actual measured value at the time of the previous life prediction and the current measured value is increased from the previous measured value. Thus, the weight ratio p is increased from the previous time. In addition to these conditions, when the X-axis condition is established such that the time from the start of the operation of the device 4B to the present time is less than 70% of the time L2, the weight ratio p is increased by 10% than the previous time. In addition, when the time from the start of the operation of the device 4B to the present time is 70% or more of the time L2 and an X-axis condition such as less than 80% is established, the weight ratio p is increased by 20% from the previous time. Moreover, when the time from the start of the operation of the device 4B to the present time is 80% or more of the time L2 and an X-axis condition such as less than 90% is established, the weight ratio p is increased by 30% from the previous time. Moreover, when the time from the start of the operation of the device 4B to the present time is 90% or more of the time L2 and an X-axis condition such as less than 100% is established, the weight ratio p is increased by 40% from the previous time.

Based on the Y-axis condition that the vibration amplitude has decreased when the actual measured value of the vibration amplitude is not constant from the actual measured value at the time of the previous life prediction and the current measured value is decreasing from the previous measured value. Therefore, it is assumed that the weight ratio p is reduced from the previous time or the same as the previous time. In addition to these conditions, when an X-axis condition is established in which the time from the start of the operation of the device 4B to the present time is less than 70% of the time L2, the weight ratio p is reduced by 10% than the previous time. In addition, when the time from the start of the operation of the device 4B to the present time is 70% or more of the time L2 and an X-axis condition such as less than 100% is established, the weight ratio p is assumed to be the same as the previous time.

As described above, by setting the weight ratio p based on the X-axis condition, the life prediction curve generation unit 55 starts the operation of the device 4B, and is an initial step, at a time when there is little accumulation of measured values, the measured curve The weighted life prediction curve C4 is generated so that the rated curve C2 is dominant compared to C3. Thereby, the preventive maintenance processing part 25 can perform the life prediction which weighted the rated life at the time when there is little accumulation of a measured value. In addition, the life prediction curve generation unit 55 applies a weight that increases the degree of control of the measured curve C3 as time passes. The life prediction curve generation unit 55 changes the life prediction curve C4 to approach the measurement curve C3 as the accumulation of the measured values increases over time. As a result, as the accumulation of the measured values increases, the preventive maintenance processing unit 25 can predict the life span weighting the accumulated measured values. In addition, by setting the weight ratio p based on the Y-axis condition, the life prediction curve generator 55 applies a weight that increases the degree of control of the measured curve C3 as the measured value of the vibration amplitude increases. The life prediction curve generation unit 55 changes the life prediction curve C4 to approach the actual curve C3 as the vibration amplitude increases. As a result, the preventive maintenance processing unit 25 can predict the lifespan corresponding to the situation where the measured value is increasing.

The life prediction unit 56 obtains the time L4 by substituting the failure threshold T into the exponential function represented by the life prediction curve C4 generated by the life prediction curve generation unit 55. The life prediction unit 56 calculates the remaining life, which is the time from the present to time L4. The life prediction unit 56 includes the failure mode specified by the failure mode specifying unit 54, the remaining life as a result 17 of the life prediction calculated by the life prediction unit 56, and the failure mode specifying unit 54 The identification score calculated by) is sent to the life data storage unit 33. The life data storage unit 33 stores the failure mode, the remaining life, and the identification score. The display device 5 displays the failure mode read from the life data storage unit 33, the remaining life, and the identification score.

12 is a flow chart showing a procedure of processing by the data processing apparatus 2 after the preventive maintenance algorithm 12 shown in FIG. 2 is selected. In step S11, the failure mode calculation unit 52 calculates the failure frequency of each failure mode of the target component. In step S12, the actual value calculation unit 51 calculates the actual value of the frequency of vibration generated in the component.

In step S13, the failure mode specifying unit 54 compares the actual frequency, which is the measured value, with the failure frequency, and specifies the failure mode of the target component. In step S14, the failure mode specifying unit 54 calculates the identification score of the specified failure mode. The representative life curve selection unit 53 selects a representative life curve and a failure threshold based on the specified failure mode.

In step S15, the life prediction curve generation unit 55 reads the representative life curve C1 and the failure threshold T selected by the representative life curve selection unit 53 from the representative life curve storage unit 34. In step S16, the life prediction curve generation unit 55 generates a life prediction curve C4 based on the read representative life curve C1.

FIG. 13 is a flowchart showing a procedure of a process for generating a life prediction curve C4 by the life prediction curve generation unit 55 shown in FIG. 6. In step S21, the life prediction curve generator 55 obtains the rated curve C2 by extending the time axis of the representative life curve C1 based on the rated life and the failure threshold T.

In step S22, the life prediction curve generation unit 55 obtains the actual measurement curve C3 based on the actual measured value of the vibration amplitude to date. In step S23, the life prediction curve generation unit 55 obtains a life prediction curve C4 according to the weight by applying a weight approaching the actual curve C3 to the rated curve C2. With this, the process of generating the life prediction curve C4 by the life prediction curve generation unit 55 ends.

In step S17 shown in FIG. 12, the life prediction unit 56 calculates the remaining life of the target component based on the life prediction curve C4 generated by the life prediction curve generation unit 55. In step S18, the life data storage unit 33 stores the failure mode specified in step S13, the remaining life calculated in step S17, and the identification score calculated in step S14. In step S19, the display device 5 displays the failure mode read from the life data storage unit 33, the remaining life, and the identification score. Thereby, the data processing apparatus 2 ends the processing shown in FIG. 12.

A part or all of the processing by the function of the data processing apparatus 2 of the first embodiment may be performed in the cloud server 3. The cloud server 3 may maintain a failure model that is a calculation formula of a failure mode value, and may calculate the failure mode value and specify the failure mode.

According to the first embodiment, the data processing device 2 includes an algorithm selection unit 26 for selecting the preventive maintenance algorithm 12 corresponding to the target component. Compared to the case where the algorithm constructed and constructed for the configuration of the production apparatus is mounted on the preventive maintenance application 10, it is possible to reduce the burden required for the construction of the preventive maintenance application 10. This achieves an effect that the burden required for the construction of an application used for data processing for preventive maintenance of the device can be reduced.

Embodiment 2.

The data processing apparatus 2 according to the second embodiment of the present invention, for each component constituting the device 4B, executes an execution cycle of life prediction for each component according to the elapsed time since the use of the component is started. Change it. The data processing apparatus 2 according to the second embodiment has the same configuration as the data processing apparatus 2 according to the first embodiment. The preventive maintenance management unit 24, which is the execution cycle management unit, changes the execution cycle according to the elapsed time since the use of the parts is started.

The increase in the measured value of the vibration amplitude becomes faster as the time nears the end of the life of the component. In the second embodiment, the preventive maintenance management unit 24 shortens the execution cycle of the life prediction and increases the execution frequency of the life prediction processing as the elapsed time after the use of the parts starts to increase. The preventive maintenance management unit 24 may change the execution cycle of the life prediction based on the weight ratio p in the first embodiment. As a result, the preventive maintenance management unit 24 increases the frequency of execution of the life prediction processing as the measured value of the vibration amplitude increases and time elapses.

According to the second embodiment, the data processing apparatus 2 executes the life prediction processing according to the degree of increase in the measured value by changing the execution cycle of the life prediction for each part according to the elapsed time since the use of the parts is started. The frequency can be changed. Thereby, the data processing apparatus 2 can make prediction accuracy of the remaining lifetime high.

The configuration shown in the above embodiments shows an example of the contents of the present invention, and it is possible to combine it with other well-known techniques, and to omit or change a part of the configuration without departing from the gist of the present invention. Do.

1: Data processing system 2: Data processing device
3: Cloud Server 4A, 4B, 4C: Device
5: display device 10: preventive maintenance application
11: Task handler 12: Preventive maintenance algorithm
13: thread 14: setting information
15: Specification parameter 16: Industry data
20: control unit 21: storage unit
22: communication unit 23: input unit
24: preventive maintenance management unit 25: preventive maintenance processing unit
26: algorithm selection unit 30: algorithm storage unit
31: industrial data storage 32: specifications parameter storage
33: life data storage unit 34: representative life curve storage unit
35: setting information storage unit 40: CPU
41: RAM 42: HDD
43: communication circuit 44: input device
45: bus 51: actual value calculation unit
52: failure mode calculation unit 53: representative life curve selection unit
54: failure mode specification unit 55: life prediction curve generation unit
56: life prediction unit

Claims (16)

An algorithm selection unit for selecting an algorithm corresponding to a target component to be predicted from among the components constituting the apparatus, from an algorithm storage unit storing an algorithm for predicting the lifetime of the components constituting the apparatus;
Based on the algorithm selected by the algorithm selection unit, a life prediction processing unit that executes a process for predicting the life of the target part.
Data processing device characterized in that it comprises. The method according to claim 1,
The algorithm selecting unit selects an algorithm based on identification information for identifying the algorithm for each component. The method according to claim 1 or claim 2,
And the algorithm selection unit selects an algorithm corresponding to the target component whose execution cycle has arrived, based on information on the execution cycle of the life prediction for each part. The method according to claim 3,
And an execution cycle management unit for managing the execution cycle for each of the parts,
The execution cycle management unit changes the execution cycle according to an elapsed time since the use of the component is started. The method according to any one of claims 1 to 4,
The algorithm selection unit inputs specification parameters, which are information specific to the target part, into the life prediction processing unit,
The life prediction processing unit performs processing of the life prediction using the algorithm selected by the algorithm selection unit and the specification parameters. The method according to any one of claims 1 to 5,
The life prediction processing unit
A failure mode calculation unit for calculating a failure mode value which is a value used for specifying a failure mode indicating the cause of the failure of the component;
Based on the failure mode value, a failure mode specifying unit for specifying a failure mode of the target component
Data processing device characterized in that it comprises. The method according to claim 6,
A first curve showing the relationship between the measured value obtained in the test for verifying the life of the component and time, and a storage unit for storing a failure threshold value, which is the measured value when the component reached a failure in the test,
The life prediction processing unit reads the first curve and the failure threshold for the target component from the storage unit, and deforms the first curve based on the failure threshold and the rated life of the target component, so that the second curve And a life prediction curve generator for generating a life prediction curve used for calculating the predicted life of the target part based on the second curve. The method according to claim 7,
The life prediction curve generation unit generates a third curve representing the relationship between the measured value and time corresponding to the failure mode value, and generates the life prediction curve by mixing the second curve and the third curve Data processing device. The method according to claim 8,
The life prediction curve generation unit generates the life prediction curve by applying a weight indicating the degree of control of the third curve in the life prediction curve to the third curve. The method according to claim 9,
The life prediction curve generation unit applies the weight that increases the degree of control of the third curve over time. The method according to claim 9,
The life prediction curve generation unit applies the weight, which increases the degree of control of the third curve as the measured value increases. The method according to claim 6,
The failure mode specifying unit calculates an identification score indicating the accuracy of the phenomenon observed as the measured value corresponding to the failure mode value, which is a phenomenon caused by the failure of the specified failure mode. . An algorithm selection unit for selecting an algorithm corresponding to a target component to be predicted from among the components constituting the apparatus, from an algorithm storage unit storing an algorithm for predicting the lifetime of the components constituting the apparatus;
Based on the algorithm selected by the algorithm selection unit, a life prediction processing unit that executes a process for predicting the life of the target part.
Data processing system characterized in that it comprises. Data processing device,
A step of selecting an algorithm corresponding to a target component to be predicted for life from among the components constituting the apparatus, from an algorithm for predicting the life of components constituting the apparatus;
Based on the selected algorithm, a step of executing a process of predicting the life of the target part is performed.
Data processing method comprising a. A data processing program that functions as a data processing apparatus for processing a computer for predicting the life of components constituting the apparatus,
A step of selecting an algorithm corresponding to a target component to be predicted for life from among components constituting the apparatus, from an algorithm for predicting the life of the component;
Based on the selected algorithm, a step of executing a process of predicting the life of the target part is performed.
A data processing program characterized by being executed on the computer. A storage medium characterized in that the data processing program according to claim 15 is stored and can be read by a computer.

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