KR102477714B1 - Predictive maintenance method of equipment through constant velocity definition for time - Google Patents

Abstract

The present invention relates to a predictive maintenance method of equipment through the constant velocity definition for the time. The method may include: an information collection step (S10); a constant velocity section collection step (S20); a calculation step (S30); a threshold setting step (S40); and a detection step (S50). According to the present invention, maintenance and replacement of equipment can be induced at an appropriate time, thereby preventing a large loss due to failure of the equipment in advance.

Description

Predictive maintenance method of equipment through constant velocity definition for time

The present invention relates to a method for predictive maintenance of a device through constant velocity definition with respect to time, and more particularly, to extract a time value between the start point and end point of an energy waveform required to perform a work process while the device is in a running state, and , Based on the extracted time value, set a detection section of unit time that can include at least two time constant sections to be set and collected, and set the threshold number for the maximum number of time constant sections that can be included in the detection section. After that, the number of time-constant speed sections of the detection section collected in the real-time operating state of the device is compared with the critical number, and an alarm is issued when an abnormal symptom of the device is satisfied, so that maintenance and replacement of the device can be performed at an appropriate time. It relates to a method for predictive maintenance of a device through a constant rate definition of time that can prevent enormous loss due to a failure of the device by inducing it to

In general, stable operation of various devices used for the automation process of facilities is very important.

For example, dozens or hundreds of devices are installed in facilities of a large-scale production plant to continuously produce products while interlocking with each other. situation may arise.

In this case, not only equipment repair costs due to downtime due to equipment failure, but also huge losses due to wasted operating costs and business effects while the equipment is stopped.

According to recent data from the Ministry of Employment and Labor and the Korea Occupational Safety and Health Administration, the number of casualties due to industrial safety accidents annually is estimated to be around 100,000, and when converted into costs, it is estimated that an annual loss of 18 trillion won is occurring.

As a way to avoid such unexpected downtime costs, it is urgent to introduce a predictive maintenance system. Although efforts are already being made to improve the problems under the name of predictive maintenance, it is necessary to develop a higher level predictive maintenance method for more efficient predictive maintenance.

[Document 0001] Republic of Korea Patent Registration No. 10-2385 (2022.04.05) [Document 0002] Republic of Korea Patent Registration No. 10-2384998 (2022.04.05)

The present invention has been proposed to solve various problems as described above, and its purpose is to extract the time value between the start point and the end point of the energy waveform required to perform the work process in the operating state of the device, and extract the Based on the set time value, set a detection section of unit time that can include at least two time constant sections to be collected, and set the threshold number for the maximum number of time constant sections that can be included in the detection section, By comparing the number of time-constant speed sections of the detection section collected in the real-time operating state of the device with the critical number, an alarm is issued when an abnormal symptom of the device is satisfied, leading to maintenance and replacement of the device at the right time Therefore, it is to provide a predictive maintenance method for a device through a constant speed definition for time that can prevent huge loss due to a device failure in advance.

In addition, various detection conditions are presented in order to efficiently search for abnormal symptoms occurring in the device, and when the detection conditions are satisfied, the device is detected as abnormal, so that abnormal symptoms generated in the device can be detected very precisely and effectively. It is an object of the present invention to provide a method for predictive maintenance of a device through constant rate definition for time that can secure excellent reliability for detection results as well as possible.

In order to achieve the above object, the predictive maintenance method of a device through constant speed definition for time according to the present invention is a device in which the amount of energy required to perform one work process in an operating state changes over time An information collection step (S10) of measuring waveform information and collecting the time between the start point at which the measured energy waveform starts and the end point at which it ends as a time value; and, the information collected through the information collection step (S10) A constant-speed section collection step in which the time values for each energy waveform of the work process repeatedly performed in the device are arranged according to the lapse of time, and time constant-speed sections of a certain unit time are repeatedly set and collected based on the arranged time values. (S20); And, in the information collection step (S10) and the constant speed section collection step (S20), a detection section of unit time that can include at least two or more time constant speed sections repeatedly set and collected is set, and the detection section is A calculation step (S30) of calculating the maximum number of time constant speed sections that can be included; and the number of time constant speed sections included in the detection section based on the maximum number of time constant speed sections for the detection section through the calculation step (S30). A threshold value setting step (S40) of setting a threshold number for; And, based on the time value for the work process that is repeatedly performed in the real-time driving state of the device, a time constant speed section of a certain unit time is collected, but the detection section and a detection step (S50) of inducing inspection and management of the device by alerting when the number of time-constant speed sections detected within a unit time of is less than the threshold number.

In addition, the constant speed section collection step (S20) is an arrangement process (S21) of arranging the time values of each work process repeatedly performed in the device based on the information collected in the information collection step (S10) according to the lapse of time. And, a setting process (S22) of setting the upper limit value and lower limit value for setting the time constant speed section and the unit time of the time constant speed section, and the time value arranged according to the flow of time does not exceed the upper limit value and the lower limit value during the set unit time It is characterized in that it consists of a section collection process (S23) of setting a section that does not occur as a time constant section and repeatedly collecting the time constant section.

In addition, instead of the calculation step (S30), the average value collection for repeatedly collecting the average value of the time values included in the time constant speed section that is repeatedly set and collected in the information collection step (S10) and the constant speed section collection step (S20) Step (S60); further comprising,

In the threshold value setting step (S40), a time threshold value for the average value of the time constant speed section is set,

In the detection step (S50), based on the time value of the work process that is repeatedly performed in the real-time driving state of the device, a time constant speed section of a certain unit time is repeatedly set and collected, and the time included in the collected time constant speed section When the average value of the values exceeds the time threshold, an alarm is issued to induce inspection and management of the device;
In the information collection step (S10), the constant speed section collection step (S20), and the average value collection step (S60), the average values of the time constant speed sections repeatedly set and collected are arranged according to the lapse of time, and the arranged average values form a straight line with each other. After connecting, a time slope information collection step (S70) of collecting time slope information through the slope of the straight line; further comprising,
In the threshold value setting step (S40), a threshold value of the time slope for the average value of the time constant speed section is set,
In the detection step (S50), the average value for the time-constant section set and collected based on the time value for the work process repeatedly performed in the real-time driving state of the device is arranged according to the lapse of time, and the arranged time-constant section A time slope value is extracted by connecting the average values of to each other with a straight line, and when the extracted time slope value exceeds the threshold value of the time slope, an alarm is issued to induce inspection and management of the device.

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In addition, instead of the calculation step (S30), in the time constant speed section repeatedly set and collected in the information collection step (S10) and the constant speed section collection step (S20), the start point where the section starts and the end point where the section ends, and A random measurement value collection step (S80) of selecting any one point from among arbitrary points within the interval and repeatedly collecting values for points selected from a plurality of the repeatedly collected time-constant intervals as random measurement values; ,

In the threshold value setting step (S40), an arbitrary threshold value is set for an arbitrary measurement value collected in a time-constant section,

In the detection step (S50), a random point for a random point selected in the random measurement value collection step (S80) is set and collected based on a time value for a work process that is repeatedly performed in a real-time driving state of the device. Extracting the measurement value, and alerting when the extracted arbitrary measurement value exceeds the arbitrary threshold value to induce inspection and management of the device;
Random measurement values of the time-constant section, which are repeatedly collected in the random measurement value collection step (S80), are arranged according to the lapse of time, and after connecting the arranged random measurement values with a straight line, the slope of the straight line is calculated. A random gradient information collection step (S90) of collecting random gradient information through; further comprising,
In the threshold value setting step (S40), a threshold value of an arbitrary slope is set for an arbitrary measurement value of a time constant speed section,
In the detection step (S50), arbitrary measured values for a time-constant speed section set based on time values for work processes repeatedly performed in the real-time driving state of the device are arranged according to the lapse of time, and the arranged time-constant speed A random slope value is extracted by connecting arbitrary measurement values of the section with each other in a straight line, and when the extracted random slope value exceeds the threshold value of the random slope, an alarm is issued to induce inspection and management of the device.

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As described above, according to the method for predictive maintenance of a device through constant speed definition for time according to the present invention, the time value between the start point and the end point of the energy waveform required for the device to perform a work process in a running state is extracted, , Based on the extracted time value, set a detection section of unit time that can include at least two time constant sections to be set and collected, and set the threshold number for the maximum number of time constant sections that can be included in the detection section. After that, the number of time-constant speed sections of the detection section collected in the real-time operating state of the device is compared with the critical number, and an alarm is issued when an abnormal symptom of the device is satisfied, so that maintenance and replacement of the device can be performed at an appropriate time. This has the effect of preventing huge losses due to device failures in advance.

In addition, various detection conditions are presented in order to efficiently search for abnormal symptoms occurring in the device, and when the detection conditions are satisfied, the device is detected as abnormal, so that abnormal symptoms generated in the device can be detected very precisely and effectively. In addition, there is an effect of securing excellent reliability for the detection result.

1 is a block diagram of a method for predictive maintenance of a device through constant speed definition with respect to time according to an embodiment of the present invention.
2 to 13 are diagrams for explaining a method for predictive maintenance of a device through constant speed definition for time shown in FIG. 1;

A method for predictive maintenance of a device through constant velocity definition with respect to time according to a preferred embodiment of the present invention will be described in detail based on the accompanying drawings. Detailed descriptions of well-known functions and configurations that may unnecessarily obscure the subject matter of the present invention will be omitted.

1 to 13 illustrate a predictive maintenance method of a device through constant velocity definition with respect to time according to an embodiment of the present invention. Block diagrams of the maintenance method, FIGS. 2 to 13 each show diagrams for explaining the predictive maintenance method of the device through the constant speed definition for time shown in FIG. 1 .

As shown in FIG. 1, the predictive maintenance method 100 of a device through constant speed definition with respect to time according to an embodiment of the present invention includes an information collection step (S10), a constant speed section collection step (S20), and a calculation step. (S30), a threshold setting step (S40), and a detection step (S50).

In the information collection step (S10), the energy waveform information in which the amount of energy required to perform one work process in the operating state of the device changes over time is measured, from the starting point at which the measured energy waveform starts. This is the step of collecting the time between the ending points as time values.

Normally, devices that are installed in large facilities and operate organically perform a specific work process repeatedly. At this time, the energy of the device used to perform the work process is the current (power), the frequency of the supply power, and the vibration generated by the device. , noise, etc. can optionally be used.

For example, when a device such as a puncher performing a work process of drilling a hole in a material shows the current supplied to the device as the energy required to perform the work process over time, the waveform shown in FIG. is shown

Here, the time value of the energy waveform is the time from the start point at which the energy waveform starts (the point at which the work process starts through the device) to the end point at which the energy wave ends (the point at which the work process ends through the device). It is a time value for the length. Even if one work process is completed in a device, a low current value is maintained in a device that does not completely stop to perform a repetitive work process. In order to easily obtain the energy for the work process, with a reference value having a predetermined magnitude set as the starting point and the time point when the energy waveform increases above the reference value as the end point, the point when it reaches less than the reference value It is desirable to easily obtain a time value from a waveform.

The constant speed section collection step (S20) arranges the time values for each energy waveform of the work process repeatedly performed in the device collected through the information collection step (S10) according to the lapse of time, and the arranged time values A step of repeatedly setting and collecting time-constant sections of a certain unit time based on

It consists of an arrangement process (S21), a setting process (S22), and a section collection process (S23).

The arrangement process (S21) is a process of arranging the time value of each work process repeatedly performed in the device according to the lapse of time based on the information collected in the information collection step (S10).

That is, as shown in FIG. 3, when the device repeatedly performs a work process, time values can be repeatedly collected. If the collected time values are arranged according to the lapse of time, they can be represented as shown in FIG. have.

The setting process (S22) is a process of setting the upper and lower limit values for setting the time constant speed section and the unit time of the time constant speed section.

Here, the unit time of the upper limit value and the lower limit value and the time constant speed section can be variously formed with appropriate values in consideration of factors such as driving conditions and usage environment of the device, and the unit time of the time constant speed club is at least two It is set to a time that includes the above time values, but it can be set in time units such as days, months, years, etc. at a minimum of several seconds.

The section collection process (S23) is a process of repeatedly collecting the time-constant section by setting a section that does not exceed the upper limit value and the lower limit value during a unit time in which a time value arranged according to the lapse of time is set.

That is, as shown in FIG. 4, if the unit time is maintained without exceeding the upper limit value and the lower limit value for which the time value is set, the section of the unit time is the time constant speed section, and the time constant speed section is repeated. collect

At this time, if the time value exceeds the upper limit value or the lower limit value within the unit time, the excess portion is excluded, and the time constant section is again tracked and collected from the time value next to the time value exceeding the upper limit value or the lower limit value.

Through the above process, the time constant speed section is repeatedly set and collected based on the time value for the work process repeatedly performed by the device.

In the calculating step (S30), a detection section of unit time that can include at least two time constant speed sections repeatedly set and collected in the information collection step (S10) and the constant speed section collection step (S20) is set, and the detection section This is a step of calculating the maximum number of time constant speed sections that can be included in .

For example, if the unit time of the time constant speed section collected in the constant speed section collection step (S20) is 1 minute and the unit time of the detection section is set to 1 hour (60 minutes) in the calculation step (S30), the set detection The maximum number of time-constant sections that can be maximally detected within a unit time of the section is naturally calculated as 60.

Here, the detection section is set as a unit time that can include at least two or more time constant speed sections. Of course there is.

The threshold value setting step (S40) is a step of setting the number of thresholds for the number of time-constant sections included in the detection section based on the maximum number of time-constant sections of the detection section through the calculation step (S30).

Here, the threshold number for the number of time-constant speed sections of the detection section is a threshold number for detecting abnormal symptoms of the device, and may be set to various numbers in consideration of the type of device, usage environment, life span, unit time of the detection section, etc. As described above, for example, the detection section of 1 hour, which can include up to 60 time-constant sections having a unit time of 1 minute, is set to 57 as the threshold number for the number of time-constant sections. At this time, , the threshold number set is a number set as an example.

It goes without saying that the threshold number can be divided into an alarm threshold number, a risk threshold number, and the like, and various levels of alarm can be formed to alert an abnormal symptom of the device.

In the detection step (S50), a time constant speed section of a certain unit time is collected based on a time value for a work process that is repeatedly performed in a real-time driving state of the device, and the time constant speed section detected within the unit time of the detection section In this step, when the number is less than the threshold number, an alarm is issued to induce inspection and management of the device.

As loads, damages, and deterioration are formed in normal equipment, time values that exceed the upper or lower limit for setting the time constant speed section often exist, and these time values lead to frequent exclusion of the set time constant speed section. If the number of time constant sections included in the unit time detection section gradually decreases, it can be seen that the soundness (state) of the device is not good.

That is, as shown in FIG. 5, based on the time value repeatedly collected in the real-time driving state of the device, time constant speed sections of 1 minute unit time are repeatedly collected, but the time constant rate included in the detection period of 60 minute unit time units. If the number of sections is equal to or greater than the threshold number set in the threshold value setting step (S40), the device is detected in a stable state, and conversely, if the number of time-constant sections included in the detection section is less than the threshold number, the device is placed in a slightly unstable state. It is a method of inducing inspection and management of equipment by detecting signs of abnormality before equipment failure occurs by detecting and alerting. Economical loss that may occur due to sudden failure of equipment as a whole stops operation of the equipment is prevented in advance. lead to prevent

On the other hand, instead of the calculation step (S30), the average value collection for repeatedly collecting the average value of the time values included in the time constant speed section that is repeatedly set and collected in the information collection step (S10) and the constant speed section collection step (S20) It further includes; step (S60).

That is, as shown in FIG. 6, it is a process of collecting the average value of the time values included in the time constant speed section repeatedly collected through the process of collecting the constant speed section (S20), and information on the average value thus collected. is the basis for setting the threshold for the average value of the time constant speed section in the threshold value setting step (S40).

Then, in the threshold value setting step (S40), a time threshold value for the average value of the time constant speed section is set.

Here, the time threshold for the average value of the time constant speed section is a value for alarming when the time average value of the time constant speed section abnormally increases or decreases, taking into account the type of device, usage environment, lifespan, size of the time constant speed section, etc. It can be set in various numbers with values of various sizes. For example, the time threshold for the average value is divided into an alarm threshold value, a risk threshold value, etc., and the level of the alarm is formed in various ways to detect abnormal symptoms of the device. Of course you can be warned.

Then, in the detection step (S50), based on the time value for the work process that is repeatedly performed in the real-time driving state of the device, a time constant speed section of a certain unit time is repeatedly set and collected, and the collected time constant speed section If the average value of the included time values exceeds the time threshold, an alarm is issued to induce inspection and management of the device.

That is, as shown in FIG. 7, the average value of the time values of the time-constant section repeatedly collected in the real-time driving state of the device is the time threshold for the average value of the time-constant section set in the threshold value setting step (S40). If it does not exceed, the device is detected in a stable state, and conversely, if the average value of the time constant speed section exceeds the time threshold, the device is detected and alarmed in a slightly unstable state. It is a method of inducing inspection and management of equipment, and induces to prevent economic loss that may occur when the entire operation of the facility is stopped due to a sudden failure of the equipment.

In addition, in the information collection step (S10), the constant speed section collection step (S20), and the average value collection step (S60), the average values of the time constant speed sections repeatedly set and collected are arranged according to the lapse of time, and the arranged average values are mutually After connecting with a straight line, a time tilt information collection step (S70) of collecting time tilt information through the slope of the straight line; is further included.

That is, as shown in FIG. 6 , if the average value of the time values of the time constant section is arranged according to the lapse of time and then connected with a straight line, it can be represented as shown in FIG. 8 .

At this time, the slope value of the straight line connecting the average value of the time-constant speed section can be divided into an ascending slope value (positive number) in which the slope rises and a descending slope value (negative number) in which the slope descends, but the slope value is digitized as an absolute value. to collect

Then, in the threshold value setting step (S40), a threshold value of the time slope for the average value of the time constant speed section is set.

Here, the time slope threshold for the average value of the time constant speed section is a value for alarming when the slope value of a straight line connecting the average value of the time constant speed section and the average value of other time constant speed sections adjacent to each other increases abnormally. Not only can it be set to a gradient value of various sizes in consideration of the type of device, usage environment, life span, and average value of the time-constant section, but also the time-slope threshold for the average value of the time-constant section is set to two or more threshold values, for example For example, it is possible to set an alarm threshold value, a risk threshold value, etc. to form various alarm levels to alarm abnormal signs of the device.

Then, in the detection step (S50), based on the time value for the work process repeatedly performed in the real-time driving state of the device, the average value for the time constant speed section set and collected is arranged according to the lapse of time, and the arranged A time slope value is extracted by connecting the average values of the time constant speed sections with each other in a straight line, and when the extracted time slope value exceeds the threshold value of the time slope, an alarm is issued to induce inspection and management of the device.

That is, as shown in FIG. 9 , the slope value of the straight line connecting the average values of the time values of the time constant section repeatedly collected in the real-time driving state of the device is the time slope set in the threshold value setting step (S40). If the threshold value is not exceeded, the device is detected in a stable state, and conversely, if the slope value of the straight line connecting the average values of the time-constant section exceeds the time slope threshold value, the device is detected in a slightly unstable state and an alarm is issued to prevent the device from malfunctioning. It is a method of inducing inspection and management of equipment by detecting abnormal signs of equipment in advance before it occurs, leading to prevent economic loss that may occur due to sudden equipment failure due to overall shutdown of the facility. .

As an example, in FIG. 9 , the time slope threshold is set to 5°, and an anomaly symptom of the device is compared and detected by comparing the slope value of a straight line connecting the average value of the real-time time constant speed section of the device to the set time slope threshold value. it did

On the other hand, instead of the calculation step (S30), in the time constant speed section repeatedly set and collected in the information collection step (S10) and the constant speed section collection step (S20), the start point where the section starts and the end point where the section ends, and It further includes a random measurement value collection step (S80) of selecting any one point from among random points within a section and repeatedly collecting values for points selected from a plurality of time-constant sections that are repeatedly collected as random measurement values. .

That is, as shown in FIG. 10, in the random measurement value collection step (S80), a specific point in a time-constant section is selected, and a random measurement value (time value) for that point is repeatedly collected in the time-constant sections. to obtain

A plurality of time values (random measurement values) obtained in this way become a basis for detecting abnormal symptoms of the device.

Here, an intermediate point is selected as an arbitrary point of the time constant speed section and time values corresponding to the middle point of the time constant speed section are repeatedly collected and obtained. Of course, it is possible to select and use time values at various points in consideration of factors such as the environment and the environment.

Then, in the threshold value setting step (S40), an arbitrary threshold value is set for an arbitrary measurement value collected in a time-constant section.

Here, the arbitrary threshold value for the arbitrary measurement value of the time constant speed section is a value for alarming when the time value for an arbitrary point selected in the time constant speed section abnormally increases or decreases, It is possible to set a variable number of values of various sizes in consideration of the life span and the size of the time-constant section, etc. For example, an arbitrary threshold value for an arbitrary point in the time-constant section is divided into an alarm threshold value, a risk threshold value, etc. Accordingly, it is of course possible to form an alarm level in various ways to alert an abnormal symptom of the device.

Then, in the detection step (S50), an arbitrary point selected in the arbitrary measurement value collection step (S80) is set and collected based on the time value for the work process that is repeatedly performed in the real-time driving state of the device. A random measured value for is extracted, and when the extracted random measured value exceeds the certain threshold value, an alarm is issued to induce inspection and management of the device.

Here, an arbitrary point in the time-constant section collected in the real-time driving state of the device is also selected as the midpoint of the time-constant section selected in the random measurement value collection step (S80), and the midpoint of the time-constant section collected in real time. Of course, a random measurement value (time value) for is extracted and collected.

That is, as shown in FIG. 11, the time value (random measurement value) for an arbitrary point in the time constant section repeatedly collected in the real-time operating state of the device is the arbitrary threshold value set in the threshold value setting step (S40). If it does not exceed , the device is detected in a stable state, and conversely, if the time value for any point in the time constant speed section exceeds the arbitrary threshold value, the device is detected in a slightly unstable state and an alarm is issued in advance before a device failure occurs. It is a method that induces inspection and management of equipment by detecting abnormal signs of equipment, and induces to prevent economic loss that may occur due to sudden equipment failure due to overall shutdown of the facility.

In addition, the random measurement values of the time-constant section that are repeatedly collected in the random measurement value collection step (S80) are arranged according to the lapse of time, and after connecting the arranged random measurement values with a straight line, the straight line It further includes a random tilt information collection step (S90) of collecting random tilt information through the tilt.

That is, as shown in FIG. 10, if arbitrary measured values for arbitrary points in the time constant section are arranged according to the lapse of time and then connected in a straight line, it can be represented as shown in FIG. 12.

At this time, the slope value of the straight line connecting the arbitrary measured values of the time-constant speed section can be divided into an ascending slope value (positive number) in which the slope rises and a descending slope value (negative number) in which the slope descends, but both slope values are absolute values. quantified and collected.

Then, in the threshold value setting step (S40), a threshold value of an arbitrary slope for an arbitrary measured value of the time constant speed section is set.

Here, the threshold value of the random slope for the arbitrary measured value of the time constant speed section is the slope value of the straight line connecting the random measured value of the time constant speed section and the random measured value of another time constant speed section that is adjacent to each other increases abnormally. As a value for alarming in case of an emergency, not only can it be set as a slope value of various sizes in consideration of the type of device, usage environment, life span, and arbitrary measured value of the time-constant speed section, etc. Of course, the threshold value of the slope can be divided into two or more threshold values, for example, an alarm threshold value, a risk threshold value, etc., to form various alarm levels to alert abnormal symptoms of the device.

Then, in the detection step (S50), arbitrary measured values for a time-constant section set based on time values for work processes that are repeatedly performed in the real-time driving state of the device are arranged according to the lapse of time, and the arrangement A random slope value is extracted by connecting random measured values of the determined time-constant speed section with each other in a straight line, and when the extracted random slope value exceeds the threshold value of the random slope, an alarm is issued to induce inspection and management of the device.

That is, as shown in FIG. 13, the slope value of the straight line connecting arbitrary measured values of the time-constant section repeatedly collected in the real-time driving state of the device is the random slope threshold set in the threshold value setting step (S40). If it does not exceed the threshold, the device is detected in a stable state, and conversely, if the slope value of the straight line connecting arbitrary measured values in the time-constant section exceeds the random slope threshold, the device is detected in a slightly unstable state and an alarm is issued to prevent device failure. It is a method of inducing inspection and management of equipment by detecting abnormal signs of equipment before they occur, leading to prevention of economic loss that may occur due to sudden failure of the equipment, which may cause the overall operation of the facility to stop.

As an example, in FIG. 13 , the random slope threshold is set to 4°, and the anomaly symptoms of the device are compared with the slope value of a straight line connecting random measured values of the real-time time-constant section of the device to the set random slope threshold. detected by comparison.

The predictive maintenance method 100 of a device through the constant velocity definition for time of the present invention, which predicts abnormal symptoms of the device through the above process, ends from the start of the energy waveform required to perform the work process while the device is in a running state. A time value between points in time is extracted, and based on the extracted time value, a detection section of unit time that can include at least two time constant speed sections to be set and collected is set, and a time constant speed section that can be included in the detection section After setting the threshold number for the maximum number, the number of time-constant sections of the detection section collected in the real-time operating state of the device is compared with the threshold number, and an alarm is issued when the condition for suspicious abnormality of the device is met. There is an effect of preventing huge losses due to device failures in advance by inducing maintenance and replacement of devices.

In addition, various detection conditions are presented in order to efficiently search for abnormal symptoms occurring in the device, and when the detection conditions are satisfied, the device is detected as abnormal, so that abnormal symptoms generated in the device can be detected very precisely and effectively. In addition, there is an effect of securing excellent reliability for the detection result.

On the other hand, the predictive maintenance method 100 of a device through constant speed definition for time of the present invention has been described as detecting abnormal symptoms of one device performing a work process based on various information extracted from a time constant speed section. When multiple devices are used to perform a work process, time-constant sections are individually established for each device to detect abnormal symptoms of the device, or information extracted from each device's time-constant section is added and combined. Of course, it is possible to detect abnormal symptoms of all devices performing the process together.

In addition, the predictive maintenance method 100 of a device through the constant velocity definition for time of the present invention can be implemented through a combination of various electronic devices and programs capable of collecting, detecting, contrasting, and alerting the energy value of the device. is of course

The present invention has been described with reference to the embodiments shown in the accompanying drawings, but these are illustrative and not limited to the above-described embodiments, and those skilled in the art can make various modifications and equivalent embodiments therefrom. you will understand the point. In addition, of course, modifications by those skilled in the art are possible within a range that does not impair the spirit of the present invention. Therefore, the scope claimed in the present invention will not be determined within the scope of the detailed description, but will be limited by the claims described later and their technical spirit.

S10. Information collection step S20. Constant speed section collection stage
S21. Arrangement process S22. Setup process
S23. Section collection process S30. Calculation stage
S40. Threshold setting step S50. detection step
S60. Average value collection step S70. Time gradient information collection stage
S80. Optional measurement value collection step S90. Random gradient information collection step
100. Predictive maintenance method of equipment through constant velocity definition for time

Claims (6)

In the predictive maintenance method of equipment used in various facilities,
Measure the energy waveform information in which the amount of energy required to perform one work process in the operating state of the device changes over time, and measure the time between the start point and the end point of the measured energy waveform. Information collection step of collecting time value (S10);
The time value for each energy waveform of the work process repeatedly performed in the device collected through the information collection step (S10) is arranged according to the lapse of time, but the time constant of a certain unit time is based on the arranged time value. A constant speed section collection step of repeatedly setting and collecting sections (S20);
In the information collection step (S10) and the constant speed section collection step (S20), a detection section of unit time that can include at least two time constant speed sections that are repeatedly set and collected is set, and a time constant speed section that can be included in the detection section Calculation step (S30) of calculating the maximum number of;
a threshold value setting step (S40) of setting a threshold number for the number of time constant speed sections included in the detection section based on the maximum number of time constant speed sections of the detection section through the calculation step (S30); and
If the time constant section of a certain unit time is collected based on the time value of the work process that is repeatedly performed in the real-time driving state of the device, but the number of time constant section detected within the unit time of the detection section is less than the threshold number A method for predictive maintenance of a device through constant rate definition for time, characterized in that it consists of;
According to claim 1,
In the constant speed section collection step (S20),
An arrangement process (S21) of arranging the time values of each work process repeatedly performed in the device according to the lapse of time based on the information collected in the information collection step (S10);
A setting process (S22) of setting an upper limit value and a lower limit value for setting a time constant speed section and a unit time of the time constant speed section;
A section collection step (S23) of setting a section that does not exceed the upper limit value and the lower limit value as a time constant section during a unit time in which a time value arranged according to the lapse of time is set, and repeatedly collecting the time constant section. A predictive maintenance method for equipment through constant rate definition for the time
According to claim 1 or 2,
An average value collection step of repeatedly collecting the average value of the time values included in the time constant speed section that is repeatedly set and collected in the information collection step (S10) and the constant speed section collection step (S20) instead of the calculation step (S30) ( S60); but further including,
In the threshold value setting step (S40), a time threshold value for the average value of the time constant speed section is set,
In the detection step (S50), based on the time value of the work process that is repeatedly performed in the real-time driving state of the device, a time constant speed section of a certain unit time is repeatedly set and collected, and the time included in the collected time constant speed section When the average value of the values exceeds the time threshold, an alarm is issued to induce inspection and management of the device;
In the information collection step (S10), the constant speed section collection step (S20), and the average value collection step (S60), the average values of the time constant speed sections repeatedly set and collected are arranged according to the lapse of time, and the arranged average values form a straight line with each other. After connecting, a time slope information collection step (S70) of collecting time slope information through the slope of the straight line; further comprising,
In the threshold value setting step (S40), a threshold value of the time slope for the average value of the time constant speed section is set,
In the detection step (S50), the average value for the time-constant section set and collected based on the time value for the work process repeatedly performed in the real-time driving state of the device is arranged according to the lapse of time, and the arranged time-constant section A time slope value is extracted by connecting the average values of to each other with a straight line, and when the extracted time slope value exceeds the threshold value of the time slope, an alarm is generated to induce inspection and management of the device. Predictive maintenance method of equipment through
delete According to claim 1 or 2,
Instead of the calculation step (S30), in the time constant speed section repeatedly set and collected in the information collection step (S10) and the constant speed section collection step (S20), the start point where the section starts and the end point where the section ends and within the section A random measurement value collection step (S80) of selecting any one point from among arbitrary points and repeatedly collecting values for points selected from a plurality of the repeatedly collected time constant sections as random measurement values,
In the threshold value setting step (S40), an arbitrary threshold value is set for an arbitrary measurement value collected in a time-constant section,
In the detection step (S50), a random point for a random point selected in the random measurement value collection step (S80) is set and collected based on a time value for a work process that is repeatedly performed in a real-time driving state of the device. Extracting the measurement value, and alerting when the extracted arbitrary measurement value exceeds the arbitrary threshold value to induce inspection and management of the device;
Random measurement values of the time-constant section, which are repeatedly collected in the random measurement value collection step (S80), are arranged according to the lapse of time, and after connecting the arranged random measurement values with a straight line, the slope of the straight line is calculated. A random gradient information collection step (S90) of collecting random gradient information through; further comprising,
In the threshold value setting step (S40), a threshold value of an arbitrary slope is set for an arbitrary measurement value of a time constant speed section,
In the detection step (S50), arbitrary measured values for a time-constant speed section set based on time values for work processes repeatedly performed in the real-time driving state of the device are arranged according to the lapse of time, and the arranged time-constant speed A random slope value is extracted by connecting random measured values of the section with each other in a straight line, and when the extracted random slope value exceeds the threshold value of the random slope, an alarm is issued to induce inspection and management of the device. A method for predictive maintenance of equipment through constant speed definition. delete

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