JP5715287B1 - Belt tension measurement system - Google Patents

Abstract

To provide a belt tension measurement system with improved usability, in which it is easy to determine whether a result obtained by measurement satisfies a standard value, and the measurement result can be collectively confirmed after a series of measurements. A belt tension meter includes a measurement result determination unit (system control circuit) and a timer, and a storage unit (storage unit) is a tension calculated by a belt tension calculation unit (system control circuit). The value and the determination result are stored, and the time set by the timer 17 is stored in association with the measurement result. In addition, the personal computer 30 is connected to a setting unit (control unit) 31 that sets a standard value corresponding to the model number of the belt B, and a transfer unit (control unit) 31 that transfers the set standard value to the belt tension meter 10. When the belt tension meter 10 and the personal computer 30 are connected by the means, a data fetching means (control part) 31 for fetching data stored in the storage means (storing part) 16 into the personal computer is provided. [Selection] Figure 3

Description

  The present invention relates to a belt tension measuring system, and more particularly, to a sonic belt tension measuring system that measures belt tension in a non-contact manner by analyzing a belt mounting tension with sound waves.

The sonic belt tension meter is a device that can easily and accurately measure the mounting tension, which is greatly related to the belt function, in a non-contact manner by analyzing a sound wave (natural frequency) generated from the belt. The principle of measurement is that when an impact is applied to a belt stretched between pulleys, it vibrates with an irregular waveform containing high-frequency components and impact components, and eventually vibrates with an inherent regular waveform. The belt tension value is calculated by detecting a vibration waveform with a microphone and converting the detected value into a natural frequency by converting the detected value into a natural frequency. For calculating the belt tension value, the following arithmetic expression set in the tension meter is used.
(Arithmetic expression)
T = 4 × M × W × S ² × f ² × 10 ⁻⁹
T: Tension value (N)
M: Unit mass (g / mm width × m length)
W: Belt width or number of ribs (wires) (mm / R)
S: Measurement span length (mm)
f: Belt primary natural frequency measured by sensor (Hz)

  Since belts, wires, and the like are rigid and the measurement result shows a value higher than the actual tension value under the use conditions where the influence appears, the correction coefficient obtained by the calibration test is used. Therefore, at the time of measurement, it is necessary to input the length of the span to be measured, the belt mass (unit mass × width), etc. into the belt tension meter body with reference to the belt catalog. In addition, whether or not the measured belt tension value is within the standard value, that is, between the upper and lower limits with respect to the reference value (standard tension value) is also described in the catalog and the value displayed on the display screen each time. It is necessary to compare with the measured value to confirm, and the operation is complicated.

  Therefore, there is a technique for efficiently performing a measurement operation without referring to a catalog or the like in measuring belt tension by detecting belt vibration. In this technique, the unit mass of the belt corresponding to the model number of the belt is recorded in the storage unit of the belt tension meter, the belt unit mass corresponding to the input model number is obtained, and the natural frequency obtained by the measurement is obtained. The tension value of the belt is calculated from the belt width and span length input before the measurement and the unit mass obtained from the storage unit, and the tension value and the standard tension value are simultaneously displayed on the display screen (see Patent Document 1). ).

JP 2005-257350 A

  However, in the above technique, the belt tension meter itself functions only as a measuring instrument that measures the natural frequency of the belt and calculates and displays the tension value from the measured value, and the result obtained by the measurement satisfies the standard value. There is no function to determine whether or not. For this reason, it is necessary to determine whether or not the measurement result satisfies the standard of the belt by the measurer himself / herself calculating from the measurement value and the reference value displayed on the display screen. In addition, the measurement values measured continuously are sequentially displayed on the display screen, but since the belt tension meter does not have a function for saving the measurement values, the measured data is overwritten and not saved. For this reason, when measuring continuously, the operation | work which records a measurement result on a notebook etc. separately for every measurement generate | occur | produces.

  Therefore, the present invention provides a belt tension measurement system with improved usability that makes it easy to determine whether or not the result obtained by measurement satisfies the standard value, and allows the measurement result to be collectively confirmed after a series of measurements. The purpose is to do.

  A belt tension measuring system according to the present invention includes a belt tension meter that measures belt tension using vibration of the belt, a setting unit that sets a standard value corresponding to a belt model number, and a belt tension meter that sets the standard value. A belt tension measuring system comprising: a personal computer provided with transfer means for transferring to a belt; and a connecting means for connecting the belt tension meter and the personal computer, wherein the belt tension meter comprises vibration detection means for detecting vibrations; , Vibration analysis means for extracting the natural frequency of the belt from vibration, input means for inputting the belt model number, belt width and span length, the unit mass of the belt corresponding to the belt model number, and the belt model number Storage means for storing a calculation formula for calculating a reference value corresponding to the standard value, a standard value transferred by the transfer means, a natural frequency related to the belt, a belt width, a span length, and a simple value. Belt tension calculating means for calculating the belt tension value from the mass, measurement result determining means for determining the measurement result from the tension value calculated by the belt tension calculating means and the standard value, and a timer, and storing The means stores the tension value calculated by the belt tension calculating means and the determination result, and stores the time set by the timer in association with the measurement result. The personal computer is connected to the belt tension meter and the personal computer by the connecting means. It is characterized by comprising data fetching means for fetching data stored in the memory means into the personal computer when is connected.

  According to the present invention, it is easy to determine whether or not the result obtained by measurement satisfies the standard value, and a belt tension measurement system with improved usability that can collectively check the measurement result after a series of measurements is provided. It becomes possible to do.

  The belt tension meter preferably includes display means for displaying the tension value calculated by the belt tension calculating means, the reference value calculated by the calculation formula, and the result determined by the measurement result determining means. In this case, the measurement result and the determination result can be easily confirmed. In addition, it is preferable that the personal computer has a data display unit for displaying a list of data, and the data displayed on the data display unit allows the data to be confirmed in time series on the personal computer, so that inspection data can be easily managed, edited and stored. It becomes.

  The storage means preferably stores a belt tension calculation formula used in the belt tension calculation means. Further, the natural frequency and the standard frequency are preferably displayed on the display means so that the measurement result can be confirmed by frequency.

  The vibration detecting means is preferably a sonic sensor. In this case, the natural frequency of the belt can be easily extracted.

  According to the present invention, it is easy to determine whether or not the result obtained by measurement satisfies the standard value, and a belt tension measurement system with improved usability that can collectively check the measurement result after a series of measurements is provided. It becomes possible to do.

It is explanatory drawing explaining schematic structure of the belt tension measuring system which is one Embodiment to which this invention was applied. It is a front view of a belt tension meter. It is a block diagram which shows the electric constitution of a belt tension measuring system. (A) A main screen displayed on the monitor of the personal computer. (B) A setting screen displayed on the monitor of the personal computer. (A) It is an example of a time setting screen. (B) It is an example of the determination setting screen. (C) It is a terminal data setting screen. It is a flowchart which shows the basic flow measured with a belt tension meter. (A) It is an example of the LCD display in tension display mode. (B) An example in which a measured tension value and a standard tension value (recommended value) are displayed in two stages. (C) An example in which the measured tension value and the frequency value are displayed in two stages. (D) This is an example in which unit mass, belt width, and span in a predetermined select number are displayed in three stages. It is an example of the data display screen which displays the transferred data as a list.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  FIG. 1 is an explanatory view illustrating a schematic configuration of a belt tension measuring system according to an embodiment to which the present invention is applied. In the belt tension measuring system according to the embodiment of the present invention, the belt tension meter 10 having a function of measuring the belt tension using the vibration of the belt B and judging the measurement result, and the model number of the belt B to be measured are used. A personal computer 30 having means for setting a corresponding standard value and transferring it to the belt tension meter 10 is provided. The belt tension meter 10 and the personal computer 30 are connected by a USB cable (connection means) 40.

  FIG. 2 is a front view of a belt tension meter 10 according to an embodiment to which the present invention is applied. The belt tension meter 10 of the present embodiment includes a display unit 11 made of an LCD or the like above the front surface thereof, and a sheet switch (input means) 12 in which a plurality of switches are arranged on the lower side, for example. . Further, a connector part 13 for connecting a sensor part 20 for detecting the vibration of the belt in a non-contact manner is provided on the upper side surface of the belt tension meter 10 main body. In the present embodiment, a sonic sensor that uses fluctuations in sound pressure is used as the sensor unit 20 that detects the vibration of the belt in a non-contact manner.

  The sensor unit 20 includes a sound wave type microphone 21 such as a microphone, a flexible arm (flexible arm) 22, and a connector unit 23 provided on the flexible arm 22. The connector part 23 is detachably connected to the connector part 13 provided in the belt tension meter 10 main body with one touch. The sensor unit 20 may have various types according to the purpose and use environment. For example, a normal signal cable may be used instead of the flexible arm. Further, the microphone 21 may be directly connected to the connector portion 23 without using an arm or a cable.

  FIG. 3 is a block diagram showing an electrical configuration of a belt tension measuring system including the belt tension meter 10 and the personal computer 30 to which the sonic sensor unit 20 is connected. The belt tension meter 10 is mainly configured by a system control circuit 15 including a microcomputer. The system control circuit 15 stores a sheet switch 12 for inputting the belt model number, belt width, and span length, a display unit 11 for displaying measurement results and determination results, and various data. A storage unit 16 including a memory, a frequency analysis unit (vibration analysis unit) 14 that performs frequency analysis of a signal (a sound pressure signal in the case of the present embodiment) detected by the sensor unit 20, and a timer 17 that sets time And are connected. The frequency analysis unit 14 is connected to the sensor unit 20 via the connector unit 13. The timer 17 is set by the personal computer 30 as will be described later.

  The storage unit 16 stores the belt unit mass corresponding to the belt model number, the catalog value calculation formula for calculating the standard frequency and standard tension value corresponding to each belt model number, and the standard value transferred by the transfer means. Are stored, and these values are displayed on the display unit 11 after the calculation process in accordance with the input belt model number and belt width. The storage unit 16 stores the tension value calculated by the system control circuit (belt tension calculation means) 15 and the result of the determination made by the system control circuit (measurement result determination means) 15, and also uses the timer 17. The set time is stored in association with the measurement result.

  The personal computer 30 is mainly configured of a control unit 31 including a microcomputer. The control unit 31 stores a keyboard 32 for inputting a standard value corresponding to the belt model number, a memory 33 for storing various data, and a storage unit 16 of the belt tension meter 10. A monitor (data display unit) 34 that displays a list of data is connected. The control unit 31 is stored in the setting unit for setting the standard value or the like input with the keyboard 32 as a measurement condition, the transfer unit for transferring the set standard value to the belt tension meter 10, and the storage unit 16 of the belt tension meter 10. It has a function as a data fetching means for fetching existing data into the personal computer 30.

  Next, a belt tension measurement procedure using the belt tension meter in this embodiment will be described.

  Prior to the measurement by the belt tension meter 10, various condition settings using the personal computer 30 will be described with reference to FIGS. First, an application for setting various conditions and managing, editing, and saving inspection data is started. When the application is activated, a main screen shown in FIG. 4A is displayed on the monitor 34 of the personal computer 30. Next, the personal computer 30 and the belt tension meter 10 are connected by the USB cable 40, and the belt tension meter 10 is turned on by operating the power (POWER) button 12p of the seat switch 12 of the belt tension meter 10.

  On the main screen, reference numeral 4A denotes a “data acquisition” button, which acquires a measurement result held in the storage unit 16 of the belt tension meter 10 connected by the USB cable 40. 4B is a “measurement result display area”, and the display content is RecNo. , UnitNo. , Mass, Width, Span, SelNo. , DateTime, Tension (N), Freq (Hz), Lower, Upper, JdgType, JdgRslt. Here, RecNo. Indicates the data recording number (serial number from 1), UnitNo. Is a terminal identification number recorded in the belt tension meter 10 set in “terminal data setting” described later, Mass is a unit mass (gf / mm) at the time of measurement, and Width is a belt width (mm / R) at the time of measurement. Span is the span length (mm) at the time of measurement. Is the Sel number selected by the belt tension meter 10 at the time of measurement, that is, the measurement condition number (0 to 39), DateTime is the time of measurement (yy / mm / dd hh: MM: ss), and Tension (N) Is the measured tension value, Freq (Hz) is the measured frequency, Lower is the lower limit value determined during measurement, Upper is the upper limit value determined during measurement, and JdgType is the determination type during measurement (N: tension value Hz : Frequency-: no determination), JdgRslt indicates the determination result at the time of determination (GOOD / HIGH / LOW, ----: no determination), respectively.

  In the main screen shown in FIG. 4A, 4C is a “CSV output” button, and the measurement result displayed in 4B is saved in a CSV file. 4D is a “USTM” button, and when pressed, switches to the setting screen shown in FIG. 4B to activate USTM emulation.

  In the setting screen shown in FIG. 4B, 4E is a “measurement result area” and displays the measurement result. The displayed contents are No. , Tension (N), Freq (Hz), Judge, Is the data number (serial number from 1), Tension (N) is the acquired tension value, Freq (Hz) is the acquired frequency, Judge is the determination result of the acquired measurement value (GOOD / HIGH / LOW, − ---: No judgment).

  In the setting screen shown in FIG. 4B, reference numeral 4F denotes a “START” / “STOP” button, which starts or stops acquisition of measurement results. 4G is a “Force” / “Frequency” radio button, and sets the determination type of the measurement result. Here, Force is used in the case of determination based on the tension value (tension display mode), and Frequency is used in the case of determination based on the frequency (frequency display mode). 4H is a “High Limit” / “Low Limit” text box, and sets upper and lower limits for determination, that is, a standard value corresponding to the model number of the belt, between 0.0 and 9999.0. Note that if both High and Low are 0.0, no determination is made. If the text box is empty, it is regarded as 0.0. Reference numeral 4I denotes a “CSV output” button, which outputs the content displayed in 4E to a CSV file. Reference numeral 4J denotes a “close” button, which ends the setting screen and returns to the main screen shown in FIG.

  Next, “Option” is selected from “Menu” on the main screen shown in FIG. 4A, and then “Clock related” is selected. By this operation, the time setting screen shown in FIG. 5A is displayed. When a predetermined time is input from this time setting screen or the current time is checked and “time setting” is pressed, the set time is displayed. Is transferred to the belt tension meter 10.

  Next, “Option” is selected from “Menu” on the main screen shown in FIG. 4A, and then “Judgment setting” is selected. By this operation, the determination setting screen shown in FIG. 5B is displayed, and this determination setting screen selects whether to make a determination based on the type of determination, that is, the tension value or the frequency. Then, one of the determined measurement conditions is selected from the preset measurement conditions, and the SelNo. Select (Measurement condition number). When the determination data distribution button is clicked, the determination information is transferred to the belt tension meter 10. SelNo. Is a select number selected by the belt tension meter 10 at the time of measurement, and the measurement conditions of each Sel number are input by keyboard input on the setting screen shown in FIG. 4B or the sheet switch 12 of the belt tension meter 10. Also input by. After performing various settings, the belt tension meter 10 is turned off by pressing the power button 12p of the seat switch 12 of the belt tension meter 10, the USB cable 40 is disconnected, and the personal computer 30 and the belt tension meter 10 are connected. Disconnect the.

  FIG. 5C shows a terminal data setting screen. When “Option” is selected from “Menu” on the main screen shown in FIG. 4A and “Terminal Data Clear” on the “Data Related” tab is pressed. The measurement data stored in the storage unit 16 of the belt tension meter 10 can be cleared. Also, the terminal number of the belt tension meter 10 can be set by selecting a terminal number in the terminal number box on the “Data Related” tab and pressing “Set Terminal Number”.

  Next, referring to FIG. 6, the procedure for measurement by the belt tension meter 10 in the field will be described. FIG. 6 is a flowchart showing a basic flow of measurement by the belt tension meter. Prior to the measurement of the belt tension, the mass (MASS) button 12m, the belt width (WIDTH) button 12w, the belt span (SPAN) button 12s, and the select (SELECT) button 12t are operated, and the selection is performed using the numeric keypad. No. SelNo. , Unit mass M, belt width W and span length S are input.

  First, in step S11, the connector portion 23 provided on the flexible arm 22 of the sonic microphone 21 is connected to the connector portion 13 provided on the belt tension meter 10 main body, and the process proceeds to step S12. In step S12, the belt tension meter 10 is turned on by operating the POWER button 12p of the seat switch 12, and the process proceeds to step S13.

  In step S13, it is determined whether or not to change the select number. If it is determined that the selection number is to be changed, the process proceeds to step S14. If it is determined that the selection number is not to be changed, the process proceeds to step S15. In step S14, the select number is directly input by pressing the select button 12t and then pressing the numeric keypad, and the process proceeds to step S15.

  In step S15, it is determined whether to input a unit mass. If it is determined that the unit mass is input, the process proceeds to step S16. If it is determined that the unit mass is not input, the process proceeds to step S17. In step S16, the unit mass is input by pressing the mass button 12m and directly inputting it by operating the numeric keypad, or by selecting the belt model number N from the list displayed on the display unit 11, and the process proceeds to step S17. The storage unit 16 stores unit masses of belts corresponding to the model numbers N of a large number of belts, and the belt unit masses of the belts corresponding to the input model numbers N are obtained.

  Here, the unit mass will be described in more detail. The model number N of the belt is input by pressing the mass button 12m for a predetermined time or longer and switching the input mode to the model number input mode. In the model number input mode, a list of model numbers is displayed on the display unit 11, and a desired model number is selected from the list. At this time, “8 (UP)” and “2 (DOWN)” of the numeric keys function as an up key and a down key, respectively, and the model number is selected by operating these keys. Normally, when the mass (MASS) button 12m is pressed, the unit mass of the belt is directly input using the numeric keypad as before.

  In step S17, it is determined whether or not a belt width is input. If it is determined that the belt width is input, the process proceeds to step S18. If it is determined that the belt width is not input, the process proceeds to step S19. In step S18, the belt width button 12w is pressed, and then the numeric keypad is pressed to input the belt width value, and the process proceeds to step S19.

  In step S19, it is determined whether to input a span length. If it is determined that the span length is input, the process proceeds to step S20. If it is determined that the span length is not input, the process proceeds to step S21. In step S20, a belt span (SPAN) button 12s is pressed, and then a numeric key is pressed to input a belt span length value, and the process proceeds to step S21.

  Next, in step S21, measurement is started by pressing the MEASURE button 12M. When the measurement button 12M is pressed, the belt tension meter 10 enters the auto trigger mode, and the subsequent measurement is automatically started by detecting a signal from the sensor unit 20. The measurement is performed by measuring the sound wave (vibration sound) generated when the belt B is repelled by bringing the sonic microphone 21 close to the vicinity of the center of the span on the back surface of the belt B. The detected sound wave signal is input to the frequency analysis unit 14, and the first natural frequency f of the belt is extracted and output to the system control circuit 15. That is, the frequency analysis unit 14 extracts the natural frequency from the signal including the impact component and the high frequency component.

In the system control circuit 15, the belt primary natural frequency f detected by measurement, the belt unit mass M corresponding to the input belt model number, the directly input belt width W, and belt span length S From the value, it is derived from the equation of the arithmetic equation (T = 4 × M × W × S ² × f ² × 10 ⁻⁹ ) set in the tension meter. The belt calculation formula is stored in the storage unit 16.

  In step S23, the measurement result is displayed. A measured value and a determination result are displayed on the display unit 11 a predetermined time after receiving the vibration sound of the belt. When the tension display mode is set on the setting screen shown in FIG. 4B, the measured value is shown as a tension value as shown in FIG. Then, the determination result is shown on the right side of the measured value. The determination result is HIGH when it is higher than the setting upper limit for determination, GOOD when it is within the setting range, and LOW when it is lower than the setting lower limit. In FIG. 7A, since the measured value is determined to be higher than the setting upper limit for determination, HIGH is displayed. When the frequency display mode is set on the setting screen shown in FIG. 4B, the display unit 11 displays the frequency.

  When the frequency / tension switching button 12H is operated after the measurement result is displayed, the display on the display unit 11 is switched to the frequency display mode. Switching between the tension display mode and the frequency display mode can be repeatedly switched every time the frequency / tension switching button 12H is operated.

  Further, when the frequency / tension switching button 12H is pressed for a long time, as shown in FIG. 7B, the measured tension value is displayed on the upper stage (RES), and the standard tension value (recommended value) of the model number is displayed on the lower stage (CAT). ) Is displayed in two stages, and when the frequency / tension switching button 12H is further pressed, the measurement frequency is displayed in the upper part (RES), and the standard frequency (recommended value) of the model number is displayed in the lower part (CAT). When the frequency / tension switching button 12H is further pressed, the measured tension value is displayed in the upper stage (TEN) and the measured frequency is displayed in two stages in the lower stage (FREQ). As described above, after long-pressing the frequency / tension switching button 12H, every time the frequency / tension switching button 12H is operated, the display on the display unit 11 can be repeatedly switched to three types of two-stage display.

  If the select button 12t is pressed here, the select number SelNo. The unit mass M, belt width W and span length S are displayed in three stages. When the select button 12t is pressed and held, the select number SelNo. Recorded measurement results are displayed in chronological order, and numeric keys “8 (UP)” and “2 (DOWN)” function as an up key and a down key, respectively. By operating these keys, they are displayed in chronological order. Confirmed data can be confirmed. Here, when the select button 12t is pressed again for a long time, the screen returns to the original select screen. When the ten key is pressed in this state, the unit mass M, belt width W and span length in the number of the pressed ten key (select number SelNo.) Are displayed. S is displayed in three stages. When the select button 12t is pressed and held, the measurement result records for the select number are displayed in time series. These measurement results are stored in the storage unit 16 of the belt tension meter 10, and the time set by the timer 17 is stored in association with the measurement results, so that the measurement result records are displayed in time series. The

  Next, referring to FIG. 8, a procedure for fetching data stored in the storage unit 16 of the belt tension meter 10 into a personal computer and displaying the list on the monitor 34 of the personal computer 30 will be described.

  The belt tension meter 10 after measurement and the personal computer 30 are connected by a USB cable (connection means) 40, and the above-described application is started. When the application is activated, a main screen shown in FIG. Next, the determination setting screen shown in FIG. 5B is displayed, and after selecting a desired select number, the data acquisition button 4A is clicked on the main screen. By this operation, the measurement result at the selected select number held in the storage unit 16 of the belt tension meter 10 connected by the USB cable 40 is acquired. The acquired data is displayed in time series as shown in FIG.

  As described above, according to the belt tension meter of the present embodiment, the belt tension meter is provided with the measurement result determination means so that the belt tension meter has not only a function as a measuring instrument but also a function as an inspection instrument. Become. Therefore, it is possible to immediately and easily know whether or not the measurement result satisfies the standard value at the time of measurement, and it is easy to determine whether or not the belt tension is adjusted. For this reason, even if the measurement result is not satisfactory, the belt tension can be adjusted by repeatedly adjusting the belt tension until it falls within the preset range, and measuring it each time to check the judgment result. , Improve usability. In addition, since the personal computer includes the setting unit and the transfer unit, it becomes easy to set the standard value and other belt information that are complicated to set with the belt tension meter.

  The belt tension meter includes a timer, and the storage unit stores the tension value calculated by the belt tension calculation unit and the determination result, and stores the time set by the timer in association with the measurement result. The measured values, measurement parameters, and judgment results are stored in time series by the belt tension meter, and the data can be confirmed in time series on the personal computer by transferring the data to the personal computer by connecting to the personal computer. This facilitates the management, editing, and storage of inspection data, and eliminates the need for writing in a notebook or the like for each measurement. As a result, it is not necessary to bring in a catalog or the like in which notes or standard values are written at the measurement site, and only the belt tension meter needs to be brought into the site. The belt tension meter itself is exclusively used for on-site measurement and checking whether the measured value is within the standard value, thereby simplifying on-site work.

  Further, the belt tension meter includes a display unit that displays the tension value calculated by the belt tension calculating unit, the reference value calculated by the calculation formula, and the result determined by the measurement result determining unit. The determination result can be easily confirmed. In addition, since the personal computer has a data display unit that displays a list of data, the data displayed on the data display unit allows the data to be confirmed in time series on the personal computer, making it easy to manage, edit, and save inspection data. .

  In the present embodiment, the explanation has been made with an example in which a sound wave type sensor is used for the sensor unit. It is. In the belt tension meter according to the present embodiment, only the numeric keys are arranged. However, when the model number includes characters such as alphabets, katakana and kanji, keys corresponding to these characters are provided, for example. It is also possible to assign them to a numeric keypad for writing these characters as used in conventional mobile phones and the like. Furthermore, when the measured value is out of the standard value, for example, a warning means for warning by a warning sound may be provided.

10 Belt tension meter 11 Display section (display means)
12 Seat switch (input means)
14 Frequency analysis unit (vibration analysis means)
15 System control circuit (belt tension calculation means, measurement result judgment means)
16 Storage unit (storage means)
17 Timer 20 Sensor part (vibration detection means)
30 personal computer 31 control unit (transfer means, setting means, data fetching means)
34 Monitor (Data display part)
40 USB cable (connection method)
B belt

Claims (5)

A belt tension meter that measures belt tension using vibration of the belt;
A personal computer including setting means for setting a standard value corresponding to the model number of the belt, and transfer means for transferring the set standard value to the belt tension meter;
A belt tension measuring system comprising: a connecting means for connecting the belt tension meter and the personal computer;
The belt tension meter is
Vibration detecting means for detecting the vibration;
Vibration analysis means for extracting the natural frequency of the belt from the vibration;
Input means for inputting the model number, belt width, and span length of the belt;
A storage unit for storing a unit mass of the belt corresponding to the model number of the belt, a calculation formula for calculating a reference value corresponding to the model number of the belt, and a standard value transferred by the transfer unit;
Belt tension calculating means for calculating a tension value of the belt from the natural frequency of the belt, the belt width, the span length, and the unit mass;
Measurement result determination means for determining a measurement result from the tension value calculated by the belt tension calculation means and the standard value;
With a timer,
The storage means stores the tension value calculated by the belt tension calculation means, the reference value, and the determination result, and stores the time set by the timer in association with the measurement result,
The personal computer includes a data fetching unit that fetches data stored in the storage unit into the personal computer when the belt tension meter and the personal computer are connected by the connecting unit. Tension measurement system.   The belt tension meter includes display means for displaying the tension value calculated by the belt tension calculating means, the reference value calculated by the calculation formula, and a result determined by the measurement result determining means. The belt tension measuring system according to claim 1.   The belt tension measuring system according to claim 1, wherein the personal computer includes a data display unit that displays a list of the data.   2. The belt tension measuring system according to claim 1, wherein the storage means stores a belt tension calculation formula used in the belt tension calculating means. 2. The belt tension measuring system according to claim 1, wherein the vibration detecting means is a sonic sensor.

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