JP2022107416A - Fatigue tester management device and fatigue tester management system - Google Patents

Abstract

To allow operators to easily confirm the progress situation of a fatigue test corresponding to each of a plurality of fatigue testers.SOLUTION: A management device 3 of a fatigue tester 1 communicatively connected to a plurality of fatigue testers 1 includes: an acquisition unit 312 that acquires progress information JP indicating a progress situation of a fatigue test in each of the fatigue testers 1 from each of the fatigue testers 1; and a display control unit 313 that displays the progress information JP of the fatigue test corresponding to each of the fatigue testers 1 on an LCD 331.SELECTED DRAWING: Figure 4

Description

The present invention relates to a fatigue tester management device and a fatigue tester management system.

In the fatigue tester, various techniques for reducing the labor of the operator are known.
For example, the fatigue tester described in Patent Document 1 is provided with means for setting the amplitude and frequency range of the repeating waveform, and while the test piece is attached, the frequency is automatically changed in the set frequency range while the test piece is attached. The load mechanism (hydraulic cylinder) is driven and controlled so that the test force is applied to the test piece based on the set amplitude, and the output of the force detection means for each frequency is taken in to represent the frequency response characteristics of the system including the test piece. Create a graph and output such as display.

Japanese Unexamined Patent Publication No. 2006-292400

However, in the fatigue testing machine described in Patent Document 1, the progress status of the fatigue test is displayed on the display arranged at a position where the testing machine main body can be easily operated, so that the progress status of a plurality of fatigue testing machines can be confirmed. In order to do so, the operator had to display the progress status on the corresponding display for each fatigue tester to check it. Therefore, it may take time and effort for the operator to confirm the progress of each fatigue test of the plurality of fatigue testers.
For example, it may take several hours for one worker to confirm the progress of each fatigue test of 50 to 100 fatigue testers.

The present invention has been made in view of such circumstances, and an object of the present invention is to provide a fatigue tester management device and a fatigue tester management system capable of reducing the labor of an operator.

The fatigue tester management device according to the first aspect of the present invention is a fatigue tester management device that is communicably connected to a plurality of fatigue testers, and is used for fatigue testing in each of the plurality of fatigue testers. It includes an acquisition unit that acquires progress information indicating a progress status from each of the plurality of fatigue testers, and a display control unit that displays the progress information corresponding to each of the plurality of fatigue testers.

The fatigue tester management system according to the second aspect of the present invention is a fatigue tester management system including a plurality of fatigue testers and a management device communicatively connected to the plurality of fatigue testers. The management device corresponds to an acquisition unit that acquires progress information indicating the progress status of the fatigue test in each of the plurality of fatigue testers from each of the plurality of fatigue testers, and each of the plurality of fatigue testers. A display control unit for displaying the progress information is provided.

The fatigue tester management device according to the first aspect of the present invention and the fatigue tester management system according to the second aspect of the present invention display the progress information of the fatigue test corresponding to each of the plurality of fatigue testers. The operator can easily check the progress of the fatigue test corresponding to each of the plurality of fatigue testers. Therefore, the labor of the operator can be reduced.

It is a figure which shows an example of the structure of the management system which concerns on this embodiment. It is a figure which shows an example of the structure of a fatigue tester. It is a figure which shows an example of the change of the stress acting on a test piece. It is a figure which shows an example of the structure of the management device and the control device. It is a screen view which shows an example of the progress management screen. Each of (A) to (C) is a diagram showing another embodiment of the progress bar. It is a flowchart which shows an example of the processing of the management apparatus which concerns on this embodiment.

Hereinafter, the present embodiment will be described with reference to the drawings.

[1. Management system configuration]
FIG. 1 is a diagram showing an example of the configuration of the management system 100 according to the present embodiment.
The management system 100 includes a plurality of fatigue testing machines 1 and a management device 3.
The plurality of fatigue testers 1 include a first fatigue tester 1A, a second fatigue tester 1B, and an Nth fatigue tester. The integer N is, for example, 50 or 100.
In the present embodiment, for convenience of explanation, the plurality of fatigue testers 1 are, for example, the first fatigue tester 1A to the seventh fatigue tester 1G.
The management system 100 corresponds to an example of a “fatigue tester management system”.

Each of the first fatigue testers 1A to N fatigue testers performs a fatigue test on the test piece SP. Each of the first fatigue testers 1A to Nth fatigue testers repeatedly applies tensile stress σ to the test piece SP, for example. The tensile stress σ and the number of repetitions are preset. The number of repetitions is, for example, ¹⁰² to ¹⁰⁸ times.
The first fatigue testers 1A to Nth fatigue testers have substantially the same configuration as each other. Therefore, in the following description, when the first fatigue tester 1A to the Nth fatigue tester are not distinguished from each other, it may be described as the fatigue tester 1.
The configuration of the fatigue tester 1 will be described later with reference to FIG.

The management device 3 is communicably connected to each of the first fatigue testers 1A to Nth fatigue testers via the network NW. The management device 3 manages the progress of each fatigue test of the first fatigue tester 1A to the Nth fatigue tester.
In this embodiment, the network NW is a LAN (Local Area Network). Further, the network NW is composed of, for example, an Ethernet (registered trademark) standard cable or the like.
The configuration of the management device 3 will be described later with reference to FIG.

In the present embodiment, the network NW is composed of an Ethernet (registered trademark) standard cable or the like, but the network NW may perform wireless communication such as Wi-Fi (registered trademark).
Further, in the present embodiment, the case where the network NW is a LAN will be described, but the network NW may be a WAN (Wide Area Network) or the Internet.
When the network NW is the Internet, the management device 3 is configured as, for example, a server device.

[2. Fatigue tester configuration]
FIG. 2 is a diagram showing an example of the configuration of the fatigue tester 1. The fatigue tester 1 includes a tester main body 10 and a control unit 20.
The testing machine main body 10 executes a fatigue test of the test piece SP according to the instruction from the control unit 20. The control unit 20 controls the operation of the testing machine main body 10.

As shown in FIG. 2, the testing machine main body 10 forms a load frame on the base 11 by a pair of columns 12a and 12b and a yoke 13, and the crosshead 14 is fixed to the columns 12a and 12b. It is composed of.

A hydraulic actuator 15 is arranged on the base 11, and a lower jig 16a for fixing the lower end of the test piece SP is attached to the piston rod 15a of the hydraulic actuator 15. Further, an upper jig 16b for fixing the upper end of the test piece SP is attached to the crosshead 14 via a load cell 17.
The load cell 17 detects the test force acting on the test piece SP.

In the hydraulic actuator 15, the pressure oil direction and the pressure oil amount are controlled by the servo valve 18, and the piston rod 15a expands and contracts. As a result, the test force is applied to the test piece SP fixed between the upper jig 16b and the lower jig 16a. The stroke of the hydraulic actuator 15, that is, the displacement of the test piece SP is detected by the differential transformer 19 attached to the hydraulic actuator 15.

The control unit 20 includes a signal input / output device 21A, a control device 21B, and an input / output device 22.
The signal input / output device 21A is arranged between the testing machine main body 10 and the control device 21B, and processes various signals input / output to the control device 21B.
The signal input / output device 21A includes a first amplifier 23, a first A / D converter 24, a second amplifier 27, a second A / D converter 28, a third amplifier 25, and a D / A converter 26.

The first amplifier 23 amplifies the test force signal output from the load cell 17 and outputs it to the first A / D converter 24.
The first A / D converter 24 A / D converts the test force signal amplified by the first amplifier 23 to generate test force information, and outputs the generated test force information to the control device 21B.
The second amplifier 27 amplifies the displacement signal output from the differential transformer 19 and outputs it to the second A / D converter 28.
The second A / D converter 28 A / D-converts the displacement signal amplified by the second amplifier 27 to generate displacement information, and outputs the generated displacement information to the control device 21B.

The control device 21B generates command information based on the test force information input from the first A / D converter 24 and the displacement information input from the second A / D converter 28, and D / D the command information. Output to A converter 26.
The D / A converter 26 D / A-converts the command information input from the control device 21B, generates a command signal, and outputs the generated command signal to the third amplifier 25.
The third amplifier 25 amplifies the control signal output from the D / A converter 26 and outputs it to the servo valve 18.
The servo valve 18 controls the pressure oil direction and the pressure oil amount with respect to the hydraulic actuator 15 according to the control signal output from the third amplifier 25.

The input / output device 22 inputs the amplitude σa, average value σm, frequency, etc. of the load waveform applied to the test piece SP to the control device 21B, and outputs the load displacement characteristics, etc. of the test piece SP as test results. It has an output unit.

FIG. 3 is a diagram showing an example of a change in stress σ acting on the test piece SP.
The vertical axis of FIG. 3 indicates the stress σ acting on the test piece SP, and the horizontal axis indicates the time T.
The test execution unit 212 of the control device 21B controls the servo valve 18 so that the stress σ changes along the graph G1 shown in FIG.
The test execution unit 212 will be described later with reference to FIG.

As shown in graph G1, the change in stress σ is represented by a sine wave and is defined by the mean value σm, the amplitude σa, and the period W.
The average value σm indicates the average value of the stress σ. The amplitude σa indicates the amplitude of the stress σ. The amplitude σa is 1/2 of the difference between the maximum value σx of the stress σ and the minimum value σn of the stress σ. The period W is defined by the frequency of stress σ.

Further, the fatigue test executed by the fatigue tester 1 is continuously executed, for example, until the number of repetitions reaches NTT. The number of repetitions NTT is, for example, ¹⁰² to ¹⁰⁸ times. The number of repetitions One time of NTT corresponds to the change of stress σ in the period W.
The number of repetitions NTT corresponds to an example of "the total number of executions of the fatigue test".
In other words, the fatigue tester 1 continuously executes the fatigue test for a time of NTT times the number of repetitions of the cycle W shown in FIG. However, if it is determined that the test piece SP is broken or the test piece SP is damaged due to fluctuations in the amplitude σa or the like, the fatigue tester 1 ends the fatigue test.
The number of repetitions NTT will be described later with reference to FIG.

[3. Configuration of management device and control device]
FIG. 4 is a diagram showing an example of the configuration of the management device 3 and the control device 21B.

[3-1. Control device configuration]
The control device 21B causes the testing machine main body 10 to perform a fatigue test.
The control device 21B includes a computer having a storage device such as an HDD (Hard Disk Drive) or an SSD (Solid State Drive), an interface circuit with the signal input / output device 21A, and various electronic circuits.
The control device 21B is not limited to a computer, and may be configured by one or a plurality of appropriate circuits such as integrated circuits such as IC chips and LSIs.

The control device 21B is composed of, for example, a personal computer and controls the operation of the testing machine main body 10. The control device 21B includes a first processor 21C and a first memory 21D.
The first processor 21C is composed of a CPU (Central Processing Unit), an MPU (Micro-Processing Unit), and the like.
The first memory 21D is composed of a ROM (Read Only Memory), a RAM (Random Access Memory), and the like.

The control device 21B is not limited to a personal computer, and may be configured by one or a plurality of appropriate circuits such as integrated circuits such as IC chips and LSIs. Further, the control device 21B may be composed of, for example, a tablet terminal, a smartphone, or the like.
Further, the control device 21B may include programmed hardware such as a DSP (Digital Signal Processor) and an FPGA (Field Programmable Gate Array). Further, the control device 21B may include a SoC (System-on-a-Chip) -FPGA.

As shown in FIG. 4, the control device 21B includes a first communication unit 211, a test execution unit 212, and a first progress storage unit 213.
Specifically, the first processor 21C of the control device 21B functions as the first communication unit 211 and the test execution unit 212 by executing the first control program PR1 stored in the first memory 21D. Further, the first processor 21C of the control device 21B executes the first control program PR1 stored in the first memory 21D to cause the first memory 21D to function as the first progress storage unit 213.

The first progress storage unit 213 stores progress information JP indicating the progress status of the fatigue test executed by the fatigue tester 1. The test execution unit 212 records the progress information JP in the first progress storage unit 213.
The progress information JP includes the scheduled end date and time TS indicating the date and time when the fatigue tester 1 started the fatigue test and the scheduled end date and time information indicating the scheduled end date and time TE which is the date and time when the fatigue tester 1 is scheduled to end the fatigue test. ..
Further, the progress information JP is the number of executions information indicating the number of executions NTA, which is the number of times the fatigue tester 1 has executed the repetition of the fatigue test, and the number of times the fatigue tester 1 is scheduled to execute the repetition of the fatigue test. Scheduled count Includes scheduled count information indicating the NTR. The sum of the number of executions NTT and the scheduled number of times NTR corresponds to the number of repetitions NTT.
Further, the progress information JP is the execution time information indicating the execution time TA, which is the time when the fatigue tester 1 executes the fatigue test, and the scheduled time, which is the time when the fatigue tester 1 is scheduled to execute the repetition of the fatigue test. Includes scheduled time information indicating TR. The sum of the execution time TA and the scheduled time TR corresponds to the fatigue test time TT, which is the time required for the fatigue tester 1 to execute the fatigue test.

Further, the progress information JP is the execution count ratio information indicating the execution count ratio PNA, which is the ratio of the execution count NTA to the repetition count NTT, and the scheduled count ratio indicating the scheduled count ratio PNR, which is the ratio of the scheduled count NTR to the repeat count NTT. Contains information. The sum of the execution count ratio PNA and the scheduled count ratio PNR is 100%.
Further, the progress information JP indicates the execution time ratio information indicating the execution time ratio PA which is the ratio of the execution time TA to the fatigue test time TT, and the scheduled time ratio PR which is the ratio of the scheduled time TR to the fatigue test time TT. Includes scheduled time ratio information. The sum of the execution time ratio PA and the scheduled time ratio PR is 100%.
When the cycle W in the fatigue test is constant in the fatigue test time TT, the execution number ratio PNA coincides with the execution time ratio PA, and the scheduled number ratio PNR coincides with the scheduled time ratio PR.

Further, the progress information JP is the end date and time TF, which is the date and time when the fatigue test is completed when the fatigue tester 1 is executing the fatigue test and the fatigue test is completed before the number of executions NTA reaches the number of repetitions NTT. The end date and time information indicating the end date and time information indicating the end date and time, and the end reason information indicating the end reason RE which is the reason for the end are included.
Further, the progress information JP is the execution time ratio PB when the fatigue test is completed when the fatigue tester 1 is executing the fatigue test and the fatigue test is completed before the number of executions NTA reaches the number of repetitions NTT. Includes execution time ratio information indicating.
The execution time ratio PB is the ratio of the execution time TA to the fatigue test time TT at the end date and time TF when the fatigue test is completed.

The scheduled end date and time TE, the execution time ratio PA, the scheduled time TR, the execution time ratio PB, the end date and time TF, and the end reason RE will be described later with reference to FIG.
Further, the execution count NTT, the scheduled count NTR, and the repeat count NTT will be described later with reference to FIG. 6 (A). The execution time TA, the scheduled time TR, and the fatigue test time TT will be described later with reference to FIG. 6 (B). The execution time ratio PA and the scheduled time ratio PR will be described later with reference to FIG. 6 (C).

The first communication unit 211 controls communication with the signal input / output device 21A.
Specifically, the first communication unit 211 receives information indicating the test force detected by the load cell 17 and information indicating the displacement output from the differential transformer 19 from the signal input / output device 21A. Further, the first communication unit 211 transmits the command information output from the test execution unit 212 to the servo valve 18 to the signal input / output device 21A.

In addition, the first communication unit 211 controls communication with the management device 3.
Specifically, the first communication unit 211 transmits the progress information JP to the management device 3 via the network NW.

The test execution unit 212 controls the testing machine main body 10 so that the testing machine main body 10 executes the fatigue test.
Specifically, the test execution unit 212 generates command information for the servo valve 18 so that the stress σ acting on the test piece SP changes in a sinusoidal shape as shown in FIG. Further, the test execution unit 212 generates command information for the servo valve 18 based on the information indicating the test force detected by the load cell 17 and the information indicating the displacement output from the differential transformer 19.
Further, the test execution unit 212 records the progress information JP in the first progress storage unit 213 at a predetermined cycle. The predetermined cycle is, for example, 1 minute.

[3-2. Management device configuration]
The management device 3 manages the progress of the fatigue test of the plurality of fatigue testers 1.
The management device 3 is composed of, for example, a personal computer. The management device 3 includes a second processor 31, a second memory 32, and a display unit 33.
The second processor 31 is composed of a CPU, an MPU, and the like.
The second memory 32 is composed of a ROM, a RAM, or the like.

The management device 3 is not limited to a personal computer, and may be configured by one or a plurality of appropriate circuits such as integrated circuits such as IC chips and LSIs. Further, the management device 3 may be composed of, for example, a tablet terminal, a smartphone, or the like.

The display unit 33 includes an LCD (Liquid Crystal Display) 331, and displays various images on the LCD 331 according to the instructions of the second processor 31. The display unit 33 displays, for example, the progress management screen 400 shown in FIG. 5 on the LCD 331.
LCD 331 corresponds to an example of a "display".

As shown in FIG. 4, the management device 3 includes a second communication unit 311, an acquisition unit 312, a display control unit 313, and a second progress storage unit 321.
Specifically, the second processor 31 of the management device 3 executes the second control program PR2 stored in the second memory 32, so that the second communication unit 311, the acquisition unit 312, and the display control unit 313, Functions as. Further, the second processor 31 of the management device 3 executes the second control program PR2 stored in the second memory 32, thereby causing the second memory 32 to function as the second progress storage unit 321.

The second progress storage unit 321 stores the progress information JP indicating the progress status of the fatigue test executed by each of the plurality of fatigue testers 1 in association with the identification information that identifies each of the plurality of fatigue testers 1. .. The acquisition unit 312 records the progress information JP of each of the plurality of fatigue testers 1 in the second progress storage unit 321. The progress information JP of each of the plurality of fatigue testers 1 is read out from the second progress storage unit 321 by the display control unit 313.

The second communication unit 311 controls communication with the control device 21B.
Specifically, the second communication unit 311 receives the progress information JP from each of the control devices 21B of the plurality of fatigue testers 1 via the network NW according to the instruction from the acquisition unit 312.

The acquisition unit 312 acquires the progress information JP from each of the control devices 21B of the plurality of fatigue testers 1.
Specifically, the acquisition unit 312 acquires the progress information JP from each of the first fatigue testers 1A to Nth fatigue testers at a predetermined cycle set in advance. The predetermined cycle is, for example, 10 minutes.
The longer the predetermined cycle, the more the load on the second processor 31 can be reduced. The shorter the predetermined cycle, the more frequently the progress management screen 400 shown in FIG. 5 can be updated.

The display control unit 313 displays the progress information JP corresponding to each of the first fatigue testers 1A to Nth fatigue testers on the LCD 331. Further, the display control unit 313 updates the progress information JP displayed on the LCD 331 each time the acquisition unit 312 acquires the progress information JP from each of the first fatigue testers 1A to N fatigue testers.
Specifically, the display control unit 313 displays the progress management screen 400 shown in FIG. 5 on the LCD 331. That is, the display control unit 313 displays the progress information JP of each of the first fatigue tester 1A to the seventh fatigue tester 1G as progress bars 410 to 470. Further, the display control unit 313 displays the progress information JP in association with the date information indicating the date. In the present embodiment, the date information indicating the date is displayed on the calendar display unit CL in a calendar format. Further, the display control unit 313 displays the progress information JP in association with the identification information that identifies each of the first fatigue tester 1A to the seventh fatigue tester 1G. In this embodiment, the identification information is displayed as the testing machine number NP.
The progress bars 410 to 470, the calendar display unit CL, and the testing machine number NP will be described later with reference to FIG.

[4. Progress management screen configuration]
FIG. 5 is a screen view showing an example of the progress management screen 400. The progress management screen 400 is displayed on the LCD 331 by the display control unit 313.
As shown in FIG. 5, the progress management screen 400 displays the testing machine number NP, the calendar display unit CL, the progress bars 410 to 470, and the current date and time display unit TN.

The testing machine number NP is displayed in the leftmost column of the progress management screen 400, and corresponds to an example of identification information that identifies each of the first fatigue testing machines 1A to the Nth fatigue testing machine.
In the present embodiment, the fact that the testing machine number NP is "1" indicates the first fatigue testing machine 1A. The fact that the testing machine number NP is "2" indicates the second fatigue testing machine 1B. The fact that the testing machine number NP is "N" indicates the Nth fatigue testing machine. The integer N is, for example, 1 to 7.
The progress management screen 400 shows the progress information JP of each of the first fatigue tester 1A to the seventh fatigue tester 1G.

The calendar display unit CL is displayed at the upper end of the progress management screen 400, and displays calendar information including the date. In the present embodiment, the "year / month" is displayed at the upper part of the calendar display unit CL, and the "day" is displayed at the lower part of the calendar display unit CL.
The number indicating each day is displayed so that the day of the week can be identified. For example, the number indicating the day corresponding to Saturday is displayed in blue, and the number indicating the day corresponding to Sunday and public holidays is displayed in red. In addition, the number indicating the day corresponding to the weekday is displayed in black.

The progress bar 410 shows the progress of the fatigue test in the first fatigue tester 1A. The progress bar 420 shows the progress of the fatigue test in the second fatigue tester 1B. The progress bar 4N0 shows the progress of the fatigue test in the Nth fatigue tester.
The progress bars 410 to 470 are displayed in a rectangular shape extending in the left-right direction. The left end of each of the progress bars 410 to 470 is displayed at a position corresponding to the start date / time TS with respect to the calendar display unit CL. Further, the right end of each of the progress bars 410 to 470 is displayed at a position corresponding to the scheduled end date and time TE on the calendar display unit CL. The start date and time TS indicates the date and time when the fatigue tester 1 starts the fatigue test. Scheduled end date and time TE indicates the date and time when the fatigue tester 1 is scheduled to end the fatigue test.
Since the fatigue test has been completed in each of the 6th fatigue tester 1F and the 7th fatigue tester 1G, the progress bar 460 and the progress bar 470 are the 1st fatigue tester 1A to the 5th fatigue tester. It is displayed in a different manner from the progress bars 410 to 450 corresponding to 1E. For example, the contour lines of the progress bars 410 to 450 are displayed as solid lines, and the contour lines of the progress bars 460 and 470 are displayed as broken lines.

In the following description, the date and time when the progress information JP displayed on the progress management screen 400 is recorded in the first progress storage unit 213 by the test execution unit 212 of the control device 21B is described as the "current date and time" for convenience.
The current date and time display unit TN indicates the date and time when the progress information JP displayed on the progress management screen 400 is recorded in the first progress storage unit 213 by the test execution unit 212 of the control device 21B.
In FIG. 5, the current date / time display unit TN stores the progress information JP displayed on the progress management screen 400 at “15:12 on May 18, 2020”, and the test execution unit 212 of the control device 21B stores the first progress. It shows that it was recorded in the part 213.
In order to make it visible that the progress information JP displayed on the progress management screen 400 is the date and time recorded in the first progress storage unit 213, that is, the current date and time is "May 18, 2020", the display control unit 313. Displays the corresponding day of the calendar display unit CL in an identifiable manner. For example, the column indicating the corresponding day of the calendar display unit CL is highlighted in black and white.
Further, the fact that the current date and time is "15:12" is displayed on the current date and time display unit TN.
Further, the current date and time display unit TN includes a current date and time display line TNL indicating the current date and time. The current date and time display line TNL is a straight line that passes through the progress bars 410 to 470 and extends in the vertical direction. The position of the current date and time display line TNL in the left-right direction corresponds to the current date and time on the calendar display unit CL.

Each of the progress bars 410 to 450 is displayed so that the left side of the current date / time display line TNL and the right side of the current date / time display line TNL can be distinguished. In FIG. 5, each of the progress bars 410 to 450 is shaded on the left side of the current date and time display line TNL, and the right side of the current date and time display line TNL is displayed in white.
In each of the progress bars 410 to 450, the left side of the current date / time display line TNL corresponds to the elapsed period from the start date / time TS of the fatigue test to the current date / time. In each of the progress bars 410 to 450, the right side of the current date / time display line TNL corresponds to the period from the current date / time to the scheduled end date / time TE of the fatigue test.

The execution time ratio PA, the scheduled time TR, and the scheduled end date and time TE are displayed on each of the progress bars 410 to 450.
The execution time ratio PA is displayed on the left side of the current date and time display line TNL, and indicates the ratio of the execution time TA to the fatigue test time TT. Execution time TA indicates the time during which the fatigue test was executed by the current date and time. In other words, the execution time TA indicates the time from the start date and time TS to the current date and time. Fatigue test time TT indicates the time scheduled to be required to perform the fatigue test.
For example, in the progress bar 410, "49%" is displayed as the execution time ratio PA, indicating that 49% of the fatigue test time TT has been completed at the current date and time. Further, for example, in the progress bar 420, "35%" is displayed as the execution time ratio PA, indicating that 35% of the fatigue test time TT has been completed at the current date and time.

The scheduled time TR and the scheduled end date / time TE are displayed on the right side of the current date / time display line TNL. The scheduled end date and time TE is displayed at the right end of each of the progress bars 410 to 450. The scheduled time TR is displayed between the current date / time display line TNL and the scheduled end date / time TE.
Scheduled time TR indicates the scheduled time for repeating the fatigue test from the current date and time. In other words, the scheduled time TR indicates the time required from the current date and time to reach the scheduled end date and time TE.
For example, the progress bar 410 displays "17 days 21 hours 3 minutes" as the scheduled time TR, indicating that the fatigue test is scheduled to end "17 days 21 hours 3 minutes" from the current date and time. Further, for example, in the progress bar 420, "26 days 21 hours 3 minutes" is displayed as the scheduled time TR, indicating that the fatigue test is scheduled to be completed "26 days 21 hours 3 minutes" from the current date and time. .. That is, about one week (7 days) after the fatigue test in the first fatigue tester 1A is completed, the fatigue test in the second fatigue tester 1B is scheduled to be completed.

Scheduled end date and time TE indicates the date and time when the fatigue test is scheduled to end.
For example, in the progress bar 410, "June 5th (Friday) 12:05" is displayed as the scheduled end date and time TE, and the fatigue test is scheduled to end at "June 5th (Friday) 12:05". It is shown that. In addition, for example, in the progress bar 420, "June 12 (Friday) 12:15" is displayed as the scheduled end date and time TE, and the fatigue test is scheduled to end at "June 12 (Friday) 12:15". It shows that.

In each of the progress bar 460 and the progress bar 470, a predetermined area on the left side of the current date / time display line TNL is shaded, and the other areas are outlined. The predetermined area corresponds to the period from the start date and time of the fatigue test to the end date and time of the fatigue test.
Each of the progress bar 460 and the progress bar 470 displays the execution time ratio PB, the end date / time TF, the end reason RE, and the scheduled end date / time TE.

In each of the progress bars 460 and 470, the execution time ratio PB is displayed in a predetermined area on the left side of the current date and time display line TNL, and indicates the ratio of the execution time TB to the fatigue test time TT. The execution time TB indicates the time from the start date / time TS to the end date / time TF. The start date and time TS indicates the date and time when the fatigue test was started. End date and time TF indicates the date and time when the fatigue test was completed. Fatigue test time TT indicates the time scheduled to be required to perform the fatigue test.
For example, in the progress bar 460, "32%" is displayed as the execution time ratio PB, indicating that the fatigue test is completed at 32% of the fatigue test time TT.

The end date / time TF, the end reason RE, and the scheduled end date / time TE are displayed on the right side of each shaded predetermined area of the progress bar 460 and the progress bar 470. The scheduled end date and time TE is displayed at the right end of each of the progress bar 460 and the progress bar 470. The end date and time TF is arranged near the right end of the predetermined area shaded in each of the progress bar 460 and the progress bar 470. The end reason RE is displayed between the end date and time TF and the scheduled end date and time TE.

End date and time TF indicates the date and time when the fatigue test was completed.
For example, in the progress bar 460, the end date and time TF is displayed as "4:08 on the 16th", indicating that the fatigue test was completed at "4:08 on the 16th".
Reason for termination RE indicates the reason why the fatigue test was completed.
For example, in the progress bar 460, the reason for termination RE is displayed as "alarm", indicating that the sixth fatigue tester 1F has issued some alarm to terminate. In other words, it indicates that some abnormality has occurred in the 6th fatigue tester 1F and the fatigue test has been completed. The abnormality includes, for example, overheating of the members constituting the fatigue tester 1.
Further, for example, in the progress bar 470, the reason for termination RE is displayed as "break", indicating that the fatigue test has been completed by breaking the test piece SP. In other words, the 7th fatigue tester 1G indicates that the fatigue test has been completed normally.

The display control unit 313 can distinguish between a case where an abnormality occurs and the fatigue test is completed like the progress bar 460 and a case where the fatigue test is normally completed like the progress bar 470. For example, the display control unit 313 makes the display color of the progress bar different depending on whether the fatigue test is completed due to an abnormality or the fatigue test is normally completed. Specifically, for example, the display control unit 313 displays the progress bar in red when an abnormality occurs and the fatigue test is completed, and displays the progress bar in green when the fatigue test is completed normally. Display with.
Further, the display control unit 313 displays the progress bars 410 to 450 corresponding to the fatigue tester 1 during the fatigue test in a color different from that of the progress bars 460 and 470. The display control unit 313 displays the progress bars 410 to 450 in blue, for example.

As described with reference to FIG. 5, since the progress bars 410 to 470 are displayed on the progress management screen 400 in association with the testing machine number NP, the user can use the first fatigue testing machines 1A to the seventh fatigue. The progress of the fatigue test in each of the testing machines 1G can be easily recognized. In the present embodiment, the user includes a worker.

Further, since the scheduled end date and time TE is displayed on each of the progress bars 410 to 450 corresponding to the fatigue tester 1 during the fatigue test, the user can use the fatigue tester 1 during the fatigue test. You can easily confirm the date and time when the fatigue test is scheduled to end.

Further, since the end reason RE is displayed on each of the progress bar 460 and the progress bar 470 corresponding to the fatigue tester 1 for which the fatigue test has been completed, the user can tell the reason why the fatigue tester 1 has completed the fatigue test. Easy to check.

In the present embodiment, the progress bar 410 to the progress bar 470 in which the progress management screen 400 includes the current date and time have been described, but the embodiment is not limited to this. A progress bar indicating that the fatigue test has been completed, in other words, a progress bar indicating that the fatigue test has been performed in the past, may be displayed. In this case, it is preferable to display the operating rate of each of the fatigue testers 1. By displaying each operating rate of the fatigue tester 1, the user can properly plan a future fatigue test.

Each of FIGS. 6 (A) to 6 (C) is a diagram showing another embodiment of the progress bar.
In the progress bar of FIG. 6A, the display control unit 313 displays the execution count NTA, the scheduled count NTR, and the repeat count NTT.
The number of executions NTA is the number of times the fatigue test is repeated by the current date and time, and the scheduled number of times NTR is the number of times the fatigue test is scheduled to be repeated after the current date and time. The number of repetitions NTT is the total number of times of repetitions scheduled to be executed in the fatigue test, and is consistent with the sum of the number of executions NTA and the planned number of times NTR.

In this case, since the user can easily confirm the execution count NTA, the scheduled count count NTR, and the repeat count number NTT for each of the fatigue testers 1, the user's convenience can be improved.

The progress bar of FIG. 6A displays the execution count NTA, the scheduled count NTR, and the repeat count NTT, but the progress bar may display the execution count ratio PNA and the scheduled count ratio PNR. The execution count ratio PNA indicates the ratio of the execution count NTA to the repeat count NTT, and the scheduled count ratio PNR indicates the ratio of the scheduled count NTR to the repeat count NTT.

In the progress bar of FIG. 6B, the display control unit 313 displays the execution time TA, the scheduled time TR, and the fatigue test time TT.
The execution time TA is the time when the fatigue test is executed by the current date and time, and the scheduled time TR is the time when the fatigue test is scheduled to be repeated after the current date and time. The fatigue test time TT is the total time required to execute the fatigue test, and is equal to the sum of the execution time TA and the scheduled time TR.

In this case, the user can easily confirm the execution time TA, the scheduled time TR, and the fatigue test time TT for each of the fatigue testers 1, so that the convenience of the user can be improved.

In the progress bar of FIG. 6C, the display control unit 313 displays the execution time ratio PA and the scheduled time ratio PR.
The execution time ratio PA is the ratio of the execution time TA to the fatigue test time TT, and the scheduled time ratio PR is the ratio of the scheduled time TR to the fatigue test time TT. The sum of the execution time ratio PA and the scheduled time ratio PR is 100%.

In this case, the user can easily confirm the execution time ratio PA and the scheduled time ratio PR for each of the fatigue testers 1, so that the convenience of the user can be improved.

[5. Operation of management device]
FIG. 7 is a flowchart showing an example of processing of the management device 3 according to the present embodiment.
First, in step S101, the acquisition unit 312 determines whether or not a predetermined cycle has elapsed. The predetermined cycle is a cycle in which the display control unit 313 updates the progress management screen 400 displayed on the LCD 331, and is, for example, 10 minutes.
When the acquisition unit 312 determines that the predetermined cycle has not elapsed (step S101; NO), the process is in the standby state. When the acquisition unit 312 determines that the predetermined cycle has elapsed (step S101; YES), the process proceeds to step S103.
Then, in step S103, the acquisition unit 312 acquires information indicating the start date and time TS from each of the control devices 21B of the plurality of fatigue testers 1.
Next, in step S105, the acquisition unit 312 acquires information indicating the scheduled end date and time TE from each of the control devices 21B of the plurality of fatigue testers 1.
Next, in step S107, the acquisition unit 312 acquires information indicating the execution time ratio PA from each of the control devices 21B of the plurality of fatigue testers 1.

Next, in step S109, the acquisition unit 312 determines whether or not the fatigue test in each of the plurality of fatigue testers 1 has been completed. The acquisition unit 312 determines whether or not the fatigue test in the fatigue tester 1 has been completed, for example, based on whether or not the test execution unit 212 of the control device 21B of the fatigue tester 1 is executing the control of the fatigue test. To judge.
If the acquisition unit 312 determines that the fatigue test in the fatigue tester 1 has not been completed (step S109; NO), the process proceeds to step S115. When the acquisition unit 312 determines that the fatigue test in the fatigue tester 1 has been completed (step S109; YES), the process proceeds to step S111.
Then, in step S111, the acquisition unit 312 acquires information indicating the end date and time TF from the control device 21B of the fatigue tester 1.
Next, in step S113, the acquisition unit 312 acquires information indicating the termination reason RE from the control device 21B of the fatigue tester 1.

Next, in step S115, the acquisition unit 312 determines whether or not the progress information JP has been acquired from the control devices 21B of all the fatigue testers 1. In the present embodiment, all the fatigue testers 1 are the first fatigue tester 1A to the seventh fatigue tester 1G.
When the acquisition unit 312 determines that the progress information JP has not been acquired from the control devices 21B of all the fatigue testers 1 (step S115; NO), the process returns to step S103. When the acquisition unit 312 determines that the progress information JP has been acquired from the control devices 21B of all the fatigue testers 1 (step S115; YES), the process proceeds to step S117.
Then, in step S117, the display control unit 313 displays the progress information JP corresponding to each of the first fatigue tester 1A to the seventh fatigue tester 1G on the LCD 331. In other words, the display control unit 313 updates the progress management screen 400 displayed on the LCD 331, for example. After that, the process returns to step S101.

In this way, the display control unit 313 displays the progress information JP corresponding to each of the first fatigue tester 1A to the seventh fatigue tester 1G on the LCD 331, so that the operator can display the progress information JP corresponding to each of the first fatigue tester 1A to the seventh fatigue tester 1A to the first fatigue tester 1A. The progress information JP corresponding to each of the 7th fatigue tester 1G can be easily confirmed. Therefore, the labor of the operator can be reduced.

[6. Aspects and effects]
It will be understood by those skilled in the art that the above-described embodiment is a specific example of the following aspects.

(Section 1)
The fatigue tester management device according to the first aspect is a fatigue tester management device that is communicably connected to a plurality of fatigue testers, and shows the progress of the fatigue test in each of the plurality of fatigue testers. It is provided with an acquisition unit that acquires the progress information to be shown from each of the plurality of fatigue testers, and a display control unit that displays the progress information of the fatigue test corresponding to each of the plurality of fatigue testers.

According to the fatigue tester management device according to the first item, the display control unit displays progress information indicating the progress of the fatigue test corresponding to each of the plurality of fatigue testers on the display.
Therefore, the operator can easily confirm the progress of the fatigue test corresponding to each of the plurality of fatigue testers. Therefore, the labor of the operator can be reduced.

(Section 2)
In the management device of the fatigue tester according to the first item, the progress information includes scheduled end date and time information indicating a date and time when the fatigue test is scheduled to end.

According to the management device of the fatigue tester according to the second item, the progress information includes the scheduled end date and time information indicating the scheduled end date and time of the fatigue test.
Therefore, the operator can easily confirm the date and time when the fatigue test is scheduled to be completed for each of the plurality of fatigue testers. Therefore, the convenience of the operator can be improved.

(Section 3)
In the management device of the fatigue tester according to the first or second paragraph, the progress information includes execution number information indicating the number of times the fatigue test is repeated, and execution time information indicating the execution time of the fatigue test. , The scheduled number of times information indicating the number of times the repetition of the fatigue test is scheduled to be executed, and the scheduled time information indicating the time scheduled to execute the repetition of the fatigue test.

According to the management device of the fatigue tester according to the third item, the progress information includes execution number information indicating the number of times the fatigue test is repeated, execution time information indicating the time when the fatigue test is executed, and the above. It includes at least one of the scheduled number of times information indicating the number of times the fatigue test repetition is scheduled to be executed and the scheduled time information indicating the time scheduled to execute the fatigue test repetition.
Therefore, the operator executes the number of times the fatigue test is repeated, the time the fatigue test is executed, the number of times the fatigue test is scheduled to be repeated, and the number of times the fatigue test is repeated for each of the plurality of fatigue testers. You can easily see at least one of the times you plan to do. Therefore, the convenience of the operator can be improved.

(Section 4)
In the management device of the fatigue tester according to any one of paragraphs 1 to 3, the progress information indicates the ratio of the number of times the fatigue test is repeated to the total number of times the fatigue test is executed. The total number of executions of the fatigue test, the execution time ratio information indicating the ratio of the execution time of the fatigue test to the total execution time of the fatigue test, and the number of times the fatigue test is scheduled to be repeated. Includes at least one of the scheduled number of times ratio information indicating the ratio to the number of executions of the fatigue test and the scheduled time ratio information indicating the ratio of the time scheduled to execute the repetition of the fatigue test to the total execution time of the fatigue test. ..

According to the management device of the fatigue tester according to the fourth item, the progress information is the execution number ratio information indicating the ratio of the number of times the repetition of the fatigue test is executed to the total number of executions of the fatigue test. Execution time ratio information indicating the ratio of the time during which the fatigue test was executed to the total execution time of the fatigue test, and the ratio of the number of times the fatigue test is scheduled to be repeated to the total number of executions of the fatigue test are shown. It includes at least one of the scheduled number of times ratio information and the scheduled time ratio information indicating the ratio of the time scheduled to execute the repetition of the fatigue test to the total execution time of the fatigue test.
Therefore, for each of the plurality of fatigue testers, the operator can perform the ratio of the number of executions to the number of repetitions, the ratio of the scheduled number of times to the number of repetitions, the ratio of the execution time to the fatigue test time, and the ratio of the scheduled time to the fatigue test time. At least one of can be easily confirmed. Therefore, the convenience of the operator can be improved.

(Section 5)
In the management device of the fatigue tester according to any one of items 1 to 4, the display control unit displays the progress information as a progress bar.

According to the material testing machine described in item 5, the display control unit displays progress information indicating the progress of the fatigue test as a progress bar for each of the plurality of fatigue testing machines.
Therefore, the operator can easily confirm the progress of the fatigue test for each of the plurality of fatigue testers. Therefore, the labor of the operator can be reduced.

(Section 6)
In the management device of the fatigue tester according to any one of paragraphs 1 to 5, the display control unit displays the progress information in association with the date information indicating the date.

According to the management device of the fatigue tester according to the sixth item, the display control unit displays progress information for each of the plurality of fatigue testers in association with the date information indicating the date.
Therefore, the operator can easily confirm the progress of the fatigue test for each of the plurality of fatigue testers. Therefore, the labor of the operator can be reduced.

(Section 7)
In the management device for the fatigue tester according to any one of paragraphs 1 to 6, the display control unit associates the identification information for identifying each of the plurality of fatigue testers with the progress information. Is displayed.

According to the management device of the fatigue tester according to the seventh item, the display control unit displays the progress information in association with the identification information that identifies each of the plurality of fatigue testers.
Therefore, the operator can easily confirm the progress of the fatigue test for each of the plurality of fatigue testers. Therefore, the labor of the operator can be reduced.

(Section 8)
The fatigue tester management system according to the second aspect is a fatigue tester management system including a plurality of fatigue testers and a management device communicatively connected to the plurality of fatigue testers. Acquires progress information indicating the progress of the fatigue test in each of the plurality of fatigue testers from each of the plurality of fatigue testers, and the progress corresponding to each of the plurality of fatigue testers. It includes a display control unit that displays information.

According to the fatigue tester management system according to the eighth item, the same operation and effect as the management device of the fatigue tester according to the first item can be obtained.

[7. Other embodiments]
The fatigue tester 1 according to the present embodiment is merely an example of the embodiment of the material tester according to the present invention, and can be arbitrarily modified and applied without departing from the gist of the present invention.
For example, in the present embodiment, the case where the network NW for communicably connecting the management device 3 and the plurality of fatigue testers 1 is a LAN will be described, but the network NW may be a WAN or the Internet. When the network NW is the Internet, the management device 3 is configured as a server device.

Further, each functional unit shown in FIGS. 1, 2 and 4 shows a functional configuration, and a specific mounting form is not particularly limited. That is, it is not always necessary to implement hardware corresponding to each functional unit individually, and it is of course possible to realize a configuration in which the functions of a plurality of functional units are realized by executing a program by one processor. Further, a part of the functions realized by the software in the above embodiment may be realized by the hardware, or a part of the functions realized by the hardware may be realized by the software.

Further, the processing unit of the flowchart shown in FIG. 7 is divided according to the main processing contents in order to make the processing of the management device 3 easy to understand. It is not limited by the method and name of the processing unit shown in the flowchart of FIG. 7, and can be divided into more processing units according to the processing content, and one processing unit can be used for more processing. It can also be divided to include. Further, the processing order of the above flowchart is not limited to the illustrated example.

Further, the management device 3 of the fatigue tester 1 causes the second processor 31 to execute the second control program PR2. Further, the second control program PR2 can be recorded on a recording medium readable by a computer. As the recording medium, a magnetic or optical recording medium or a semiconductor memory device can be used. Specifically, it is a portable or fixed flexible disk, HDD, CD-ROM (Compact Disk Read Only Memory), DVD, Blu-ray (registered trademark) Disc, magneto-optical disk, flash memory, card-type recording medium, or the like. The recording medium of the formula can be mentioned. Further, the recording medium may be a non-volatile storage device such as a RAM, ROM, or HDD, which is an internal storage device included in the management device 3. Further, the second control program PR2 may be stored in a server device or the like, and the second control program PR2 may be downloaded from the server device to the management device 3.

100 management system (fatigue tester management system)
1 Fatigue tester 1A-1G 1st fatigue tester-7th fatigue tester 10 Tester body 11 Base 12a Strut 12b Strut 13 York 14 Crosshead 15 Hydraulic actuator 15a Piston rod 16a Lower jig 16b Upper jig 17 Load cell 18 Servo valve 19 Differential transformer 20 Control unit 21A Signal input / output device 21B Control device 21C 1st processor 21D 1st memory 211 1st communication unit 212 Test execution unit 213 1st progress storage unit 3 Management device 31 2nd processor 311th 2 Communication unit 312 Acquisition unit 313 Display control unit 32 Second memory 321 Second progress storage unit 33 Display unit 331 LCD
400 Progress management screen 410-470 Progress bar CL Calendar display JP Progress information NP Testing machine number NTA Number of executions NTR Scheduled number of times NTT Repeated number of times PA Execution time ratio PB Execution time ratio PNA Execution time ratio PNA Scheduled number of times ratio PR Scheduled time ratio PR1 1st control program PR2 2nd control program RE Reason for end TA, TB Execution time TE Scheduled end date and time TF End date and time TN Current date and time display TNL Current date and time display line TR Scheduled time TS Start date and time TT Fatigue test time

Claims (8)

A fatigue tester management device that is communicatively connected to multiple fatigue testers.
An acquisition unit that acquires progress information indicating the progress of the fatigue test in each of the plurality of fatigue testers from each of the plurality of fatigue testers.
A display control unit that displays the progress information corresponding to each of the plurality of fatigue testers, and a display control unit.
Fatigue tester management device. The progress information includes scheduled end date and time information indicating a date and time when the fatigue test is scheduled to end.
The management device for the fatigue testing machine according to claim 1. The progress information includes execution number information indicating the number of times the fatigue test is repeated, execution time information indicating the time during which the fatigue test is executed, and scheduled number information indicating the number of times the fatigue test is scheduled to be repeated. And at least one of the scheduled time information indicating the time scheduled to execute the repetition of the fatigue test.
The management device for the fatigue testing machine according to claim 1 or 2. The progress information is the execution number ratio information indicating the ratio of the number of times the repetition of the fatigue test is executed to the total number of executions of the fatigue test, and the total execution time of the fatigue test of the time when the fatigue test is executed. Execution time ratio information indicating the ratio to, the scheduled number ratio information indicating the ratio of the number of times the fatigue test is scheduled to be executed to the total number of times the fatigue test is executed, and the schedule to execute the repetition of the fatigue test. Includes at least one of the scheduled time ratio information, which indicates the ratio of the time to the total execution time of the fatigue test.
The management device for a fatigue tester according to any one of claims 1 to 3. The display control unit displays the progress information as a progress bar.
The management device for a fatigue tester according to any one of claims 1 to 4. The display control unit displays the progress information in association with the date information indicating the date.
The management device for a fatigue tester according to any one of claims 1 to 5. The display control unit displays the progress information in association with the identification information that identifies each of the plurality of fatigue testers.
The management device for a fatigue tester according to any one of claims 1 to 6. A fatigue tester management system including a plurality of fatigue testers and a management device communicatively connected to the plurality of fatigue testers.
The management device is
An acquisition unit that acquires progress information indicating the progress of the fatigue test in each of the plurality of fatigue testers from each of the plurality of fatigue testers.
A display control unit that displays the progress information corresponding to each of the plurality of fatigue testers, and a display control unit.
Fatigue tester management system equipped with.

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