JP2021076619A - Vibration sensor system, vibration measurement method, and vibration measurement program - Google Patents

Abstract

To provide a vibration sensor system, vibration measurement method, and vibration measurement program capable of efficiently sampling the measurement result of vibration, in a configuration for measuring the vibration of a measurement object.SOLUTION: The vibration sensor system includes: a data creation unit for creating vibration data by sampling the measurement result of a sensor for measuring the vibration of a measurement object; and a control unit for changing the sampling rate of the data creation unit on the basis of the vibration data created by the data creation unit.SELECTED DRAWING: Figure 3

Description

The present invention relates to a vibration sensor system, a vibration measurement method and a vibration measurement program.

Conventionally, a technique for detecting abnormal vibration of a measurement target has been developed. For example, Patent Document 1 (Japanese Unexamined Patent Publication No. 11-271183) discloses the following vibration data collecting device. That is, the vibration data collecting device has a data input unit that receives vibration waveform data output from the vibration sensor and performs predetermined data processing, and a predetermined amplitude value of the first vibration waveform data processed by the data input unit. A / D by sampling the vibration waveform data at a predetermined sampling frequency for the entire vibration frequency band based on the determination result of the vibration abnormality determination unit for determining whether or not the vibration threshold level is equal to or higher than the vibration threshold level of (Analog-digital) A first A / D conversion unit for conversion, a data storage unit for storing A / D-converted second vibration waveform data in the first A / D conversion unit, and at least the data storage unit are stored. It is provided with a communication interface unit for transmitting the second vibration waveform data via a digital communication line.

Japanese Unexamined Patent Publication No. 11-271183 Japanese Unexamined Patent Publication No. 7-5031

Beyond the technique described in Patent Document 1, there is a demand for a technique for efficiently sampling analog measurement results for vibration of a measurement target.

The present invention has been made to solve the above-mentioned problems, and an object of the present invention is a vibration sensor system capable of efficiently sampling the measurement result of the vibration in a configuration for measuring the vibration of the measurement target, vibration. It is to provide a measurement method and a vibration measurement program.

(1) In order to solve the above problems, the vibration sensor system according to a certain aspect of the present invention includes a data creation unit that samples the measurement result of the sensor that measures the vibration of the measurement target and creates vibration data, and the data. It includes a control unit that changes the sampling rate of the data creation unit based on the vibration data created by the creation unit.

(10) In order to solve the above problems, the vibration measurement method according to a certain aspect of the present invention is the vibration measurement method in the vibration sensor system, and the measurement result of the sensor that measures the vibration of the measurement target is sampled to vibrate. It includes a step of creating data and a step of changing the sampling rate of the measurement result based on the created vibration data.

(11) In order to solve the above problems, the vibration measurement program related to a certain aspect of the present invention is a vibration measurement program used in a vibration sensor system, and is a measurement result of a computer that measures the vibration of a measurement target. This is a program for functioning as a data creation unit that samples and creates vibration data, and a control unit that changes the sampling rate of the data creation unit based on the vibration data created by the data creation unit.

The present invention can be realized not only as a vibration sensor system provided with such a characteristic processing unit, but also as a vibration measuring device provided with such a characteristic processing unit. Further, the present invention can be realized as a semiconductor integrated circuit that realizes a part or all of the vibration sensor system.

According to the present invention, in a configuration for measuring vibration of a measurement target, the measurement result of the vibration can be efficiently sampled.

FIG. 1 is a diagram showing a configuration of a vibration sensor system according to the first embodiment of the present invention. FIG. 2 is a diagram showing an installation example of the vibration measuring device according to the first embodiment of the present invention. FIG. 3 is a diagram showing a configuration of a vibration measuring device in the vibration sensor system according to the first embodiment of the present invention. FIG. 4 is a diagram showing an example of the appearance of the vibration measuring device in the vibration sensor system according to the first embodiment of the present invention. FIG. 5 is a diagram showing a configuration of a sensor unit in the vibration measuring device according to the first embodiment of the present invention. FIG. 6 is a diagram showing a configuration of a wireless module in the vibration measuring device according to the first embodiment of the present invention. FIG. 7 is a diagram showing an example of an effective value of acceleration calculated by a control unit in the wireless module according to the first embodiment of the present invention. FIG. 8 is a diagram showing an example of a change in the effective value with respect to the sampling rate obtained from the calculation result shown in FIG. 7. FIG. 9 is a diagram showing an example of a frequency analysis result of vibration data in the wireless module according to the first embodiment of the present invention. FIG. 10 is a diagram showing a configuration of a modified example of a vibration measuring device in the vibration sensor system according to the first embodiment of the present invention. FIG. 11 is a flowchart defining an operation procedure when the vibration sensor system according to the first embodiment of the present invention processes vibration data. FIG. 12 is a flowchart defining an operation procedure when the vibration sensor system according to the first embodiment of the present invention performs the optimum sampling rate determination process. FIG. 13 is a diagram showing a configuration of a vibration sensor system according to a second embodiment of the present invention. FIG. 14 is a diagram showing a configuration of a vibration measuring device in the vibration sensor system according to the second embodiment of the present invention. FIG. 15 is a diagram showing a configuration of a wireless module in the vibration measuring device according to the second embodiment of the present invention. FIG. 16 is a diagram showing a configuration of a management device in the vibration sensor system according to the second embodiment of the present invention.

First, the contents of the embodiments of the present invention will be listed and described.

(1) The vibration sensor system according to the embodiment of the present invention includes a data creation unit that samples the measurement result of a sensor that measures the vibration of the measurement target and creates vibration data, and the data creation unit created by the data creation unit. It is provided with a control unit that changes the sampling rate of the data creation unit based on the vibration data.

With such a configuration, the vibration state of the measurement target can be grasped based on the vibration data, so that an appropriate sampling rate can be obtained. As a result, for example, the sampling rate of the data creation unit can be changed to a sampling rate according to the vibration condition of the measurement target. Therefore, since the sampling rate is faster than necessary, the amount of vibration data to be continuously sampled is increased. It is possible to prevent the increase and the increase in the memory capacity to be prepared for holding the sampled vibration data. In addition, it is possible to prevent an increase in power consumption due to a sampling rate that is faster than necessary. Therefore, in the configuration for measuring the vibration of the measurement target, the measurement result of the vibration can be efficiently sampled.

(2) Preferably, in a state where the data creation unit creates the vibration data by sampling at the first rate, the control unit sets the sampling rate to the first sampling rate based on the vibration data. Change to a second rate that is less than the rate.

With such a configuration, the presence or absence of a higher frequency vibration component can be grasped based on the vibration data of the larger first rate, so that a more appropriate second rate can be obtained.

(3) More preferably, after changing to the second rate, the control unit changes the sampling rate to the first rate when a predetermined condition not based on the vibration data is satisfied.

In this way, when the above-mentioned predetermined conditions are satisfied, the configuration of returning the second rate to the first rate makes it possible to grasp the changed vibration state even when the vibration state of the measurement target changes, for example. Therefore, it is possible to obtain the sampling rate according to the change in the vibration condition.

(4) More preferably, the predetermined condition is the arrival of a periodic timing.

In this way, by periodically returning the second rate to the first rate, for example, even when the change in the vibration condition of the measurement target cannot be predicted, it is possible to deal with the change in the vibration condition with a simple configuration. it can.

(5) More preferably, the vibration sensor system further includes an operation unit for returning the sampling rate to the first rate.

With such a configuration, for example, when the user recognizes that the vibration state of the measurement target has changed, the user can return the second rate to the first rate by operating the operation unit.

(6) Preferably, the control unit calculates a representative value of each of the vibration data created at the plurality of sampling rates, and corresponds to the sampling rate having the next smallest value among the plurality of sampling rates. Among the sampling rates whose difference from the representative value is outside the predetermined range, the maximum sampling rate is determined as the sampling rate of the data creation unit.

With such a configuration, the sampling rate can be determined without performing, for example, an FFT (Fast Fourier Transform) process, so that the process in the control unit can be simplified.

(7) Preferably, the vibration sensor system further includes a wireless slave unit that transmits a wireless signal including the vibration data and a wireless parent that transmits the vibration data included in the wireless signal received from the wireless slave unit. The wireless slave unit includes the control unit and includes a unit and a management device for processing the vibration data received from the wireless master unit.

In this way, with the configuration in which the wireless slave unit includes the control unit, for example, after the control unit changes the sampling rate in the data creation unit to an appropriate sampling rate, the vibration data created by the data creation unit is transferred to the wireless slave unit. Can be sent. As a result, it is possible to prevent the vibration data having a data length longer than necessary from being wirelessly transmitted, so that the power consumption of the wireless slave unit can be suppressed. In addition, it is possible to reduce the possibility that vibration data is missing in wireless transmission. Therefore, for example, in a configuration in which the wireless slave unit can perform two-way communication, the frequency of retransmitting the missing vibration data can be reduced.

(8) More preferably, the wireless slave unit transmits the wireless signal by one-way communication.

With such a configuration, the functions and processing of the wireless slave unit can be simplified. Further, since the wireless slave unit does not need to listen for the wireless signal from another device such as the wireless master unit, the wireless slave unit can be turned off, for example, during the period when the wireless slave unit does not transmit the wireless signal. As a result, the power consumption of the wireless slave unit can be suppressed.

(9) Preferably, the vibration sensor system further includes a wireless slave unit that transmits a wireless signal including the vibration data and a wireless parent that transmits the vibration data included in the wireless signal received from the wireless slave unit. It includes a machine and a management device that processes the vibration data received from the wireless master unit, and the management device includes the control unit.

In this way, the configuration in which the management device includes the control unit can simplify, for example, the configuration of the wireless slave unit. Further, for example, when a plurality of data creation units are provided in the vibration sensor system, the management device can comprehensively process the vibration data created by each data creation unit, so that the vibration status at each measurement site can be determined. The sampling rate of each data creation unit can be changed while taking this into consideration.

(10) The vibration measurement method according to the embodiment of the present invention is a vibration measurement method in a vibration sensor system, which includes a step of sampling the measurement result of a sensor that measures the vibration of the measurement target and creating vibration data. It includes a step of changing the sampling rate of the measurement result based on the created vibration data.

With such a configuration, the vibration state of the measurement target can be grasped based on the vibration data, so that an appropriate sampling rate can be obtained. As a result, for example, the sampling rate of the data creation unit can be changed to a sampling rate according to the vibration condition of the measurement target. Therefore, since the sampling rate is faster than necessary, the amount of vibration data to be continuously sampled is increased. It is possible to prevent the increase and the increase in the memory capacity to be prepared for holding the sampled vibration data. In addition, it is possible to prevent an increase in power consumption due to a sampling rate that is faster than necessary. Therefore, in the configuration for measuring the vibration of the measurement target, the measurement result of the vibration can be efficiently sampled.

(11) The vibration measurement program according to the embodiment of the present invention is a vibration measurement program used in a vibration sensor system, in which a computer samples the measurement results of a sensor that measures the vibration of a measurement target and collects vibration data. This is a program for functioning as a data creation unit to be created and a control unit for changing the sampling rate of the data creation unit based on the vibration data created by the data creation unit.

With such a configuration, the vibration state of the measurement target can be grasped based on the vibration data, so that an appropriate sampling rate can be obtained. As a result, for example, the sampling rate of the data creation unit can be changed to a sampling rate according to the vibration condition of the measurement target. Therefore, since the sampling rate is faster than necessary, the amount of vibration data to be continuously sampled is increased. It is possible to prevent the increase and the increase in the memory capacity to be prepared for holding the sampled vibration data. In addition, it is possible to prevent an increase in power consumption due to a sampling rate that is faster than necessary. Therefore, in the configuration for measuring the vibration of the measurement target, the measurement result of the vibration can be efficiently sampled.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. The same or corresponding parts in the drawings are designated by the same reference numerals, and the description thereof will not be repeated. In addition, at least a part of the embodiments described below may be arbitrarily combined.

<First Embodiment>
[Configuration and basic operation]
FIG. 1 is a diagram showing a configuration of a vibration sensor system according to the first embodiment of the present invention.

With reference to FIG. 1, the vibration sensor system 301 includes a plurality of vibration measuring devices 101, a plurality of access points (wireless master units) 151, and a management device 181.

FIG. 2 is a diagram showing an installation example of the vibration measuring device according to the first embodiment of the present invention.

With reference to FIG. 2, the equipment 10 includes rotating portions 9A, 9B, 9C. Hereinafter, each of the rotating portions 9A, 9B, and 9C will also be referred to as a rotating portion 9.

The rotating unit 9C is, for example, a motor. The rotational power generated by the rotating unit 9C is transmitted via the rotating units 9B and 9A.

The vibration measuring device 101 is provided in the equipment 10. More specifically, the vibration measuring device 101 includes, for example, an acceleration sensor and is fixed to the equipment 10. The vibration measuring device 101 measures the vibration of the equipment 10.

In FIG. 2, the three vibration measuring devices 101 are attached to, for example, the rotating portions 9A, 9B, and 9C of the equipment 10.

With reference to FIG. 1 again, the vibration measuring device 101 measures the vibration of the equipment 10 and broadcasts a radio signal including vibration data information indicating the measurement result.

The access point 151 can perform wired communication with the management device 181 via the internal network 11, for example.

When the access point 151 receives the vibration data information from the vibration measuring device 101, the access point 151 relays the received vibration data information and transmits the received vibration data information to the management device 181 via the internal network 11.

The management device 181 receives vibration data information from the access point 151, and manages the equipment 10 based on the received vibration data information. Specifically, the management device 181 detects, for example, imbalance, misalignment, abnormal vibration due to resonance, abnormal vibration of the bearing, etc. in the rotating portion 9 by analyzing the vibration of the equipment 10, and maintains the equipment 10. And make an abnormality diagnosis.

The access point 151 is configured to wirelessly receive vibration data information from the vibration measuring device 101, but the present invention is not limited to this. The access point 151 may be configured to receive vibration data information from the vibration measuring device 101 by wire.

Further, the configuration is such that wired communication is performed between the access point 151 and the management device 181 but the present invention is not limited to this. The configuration may be such that wireless communication is performed between the access point 151 and the management device 181.

Further, the access point 151 is configured to receive vibration data information from the vibration measuring device 101 without going through another device, but the present invention is not limited to this. For example, a relay device may be provided between the access point 151 and the vibration measuring device 101, and the access point 151 may be configured to receive vibration data information from the vibration measuring device 101 via the relay device.

FIG. 3 is a diagram showing a configuration of a vibration measuring device in the vibration sensor system according to the first embodiment of the present invention.

With reference to FIG. 3, the vibration measuring device 101 includes a sensor unit 21, a wireless module (wireless slave unit) 22, a battery 23, and an operation unit 24. The battery 23 may be provided outside the vibration measuring device 101.

The sensor unit 21 and the wireless module 22 in the vibration measuring device 101 operate using the electric power supplied from the battery 23. At least one of the sensor unit 21 and the wireless module 22 may operate using the electric power received from the system.

Specifically, the sensor unit 21 is a MEMS (Micro Electro Electrical Systems) digital accelerometer whose sampling rate can be changed, samples an analog signal corresponding to the vibration of the equipment 10, and digital vibration data which is a sampling result. Is output to the wireless module 22.

The wireless module 22 is realized by, for example, a dedicated semiconductor integrated circuit, and transmits vibration data received from the sensor unit 21 to the access point 151.

FIG. 4 is a diagram showing an example of the appearance of the vibration measuring device in the vibration sensor system according to the first embodiment of the present invention.

With reference to FIGS. 3 and 4, the operation unit 24 is provided, for example, on the surface of the housing of the vibration measuring device 101. The operation unit 24 is used to return the sampling rate in the own vibration measuring device 101 to the initial rate (hereinafter, also referred to as the first rate).

The operation unit 24 is specifically a button. The operation unit 24 may be a switch or the like. The operation unit 24 accepts an on operation such as pressing by the user, and outputs on operation information indicating the on operation to the wireless module 22.

FIG. 5 is a diagram showing a configuration of a sensor unit in the vibration measuring device according to the first embodiment of the present invention.

With reference to FIG. 5, the sensor unit 21 includes a sensor 25, a filter unit 26, an AD (analog-digital) conversion unit (data creation unit) 27, and a clock generation unit 28.

The sensor 25 in the sensor unit 21 measures the vibration of the measurement target. Specifically, the sensor 25 is, for example, an acceleration sensor, and is attached so as to be in close contact with the equipment 10. The sensor 25 measures its own acceleration as the acceleration of the equipment 10, and outputs an analog measurement signal Sa indicating the measurement result to the AD conversion unit 27.

The clock generation unit 28 generates a clock signal and outputs the generated clock signal to the AD conversion unit 27. The frequency of the clock signal in the clock generation unit 28 can be changed from the outside of the clock generation unit 28.

The clock generation unit 28 sets the frequency of the clock signal according to the control of the wireless module 22. More specifically, the clock generation unit 28 receives a setting instruction S1 indicating the frequency of the clock signal to be set from the wireless module 22, and sets the frequency of the clock signal according to the received setting instruction S1.

The clock generation unit 28 may be configured to set the frequency of the clock signal according to the value of a clock register (not shown) rewritable by the wireless module 22.

The AD conversion unit 27 samples the measurement result of the sensor 25 and creates vibration data Dv.

Specifically, the AD conversion unit 27 samples the measurement signal Sa at the sampling rate set by the wireless module 22.

More specifically, the AD conversion unit 27 operates according to the sampling timing of the clock signal received from the clock generation unit 28, and samples the measurement signal Sa received from the sensor 25 at each sampling timing. The AD conversion unit 27 creates digital vibration data Dv showing the sampling result, and outputs the created vibration data Dv to the filter unit 26.

The filter unit 26 is, for example, a digital filter and includes a low-pass filter capable of changing the cutoff frequency. The filter unit 26 sets the cutoff frequency according to the control of the wireless module 22. More specifically, the filter unit 26 receives, for example, a setting command S2 indicating a cutoff frequency to be set from the wireless module 22, and sets the cutoff frequency according to the received setting command S2.

The filter unit 26 attenuates the frequency component of the vibration data Dv received from the AD conversion unit 27 at each sampling timing, which is equal to or higher than the cutoff frequency, and outputs the attenuated vibration data Dv to the wireless module 22.

The filter unit 26 may have a configuration in which the cutoff frequency is set according to the value of a filter register (not shown) that can be rewritten by the wireless module 22.

Further, the filter unit 26 may be configured to hold the vibration data Dv after attenuation in a data holding register (not shown).

Further, the sensor unit 21 is configured to filter digital signals, but the present invention is not limited to this. The sensor unit 21 may be configured to filter analog signals. Specifically, in the sensor unit 21, instead of the filter unit 26, a filter unit having an analog filter function may be provided between the sensor 25 and the AD conversion unit 27.

FIG. 6 is a diagram showing a configuration of a wireless module in the vibration measuring device according to the first embodiment of the present invention.

With reference to FIG. 6, the wireless module 22 includes a memory 30, a control unit 31, and a transmission unit 32.

The memory 30 in the wireless module 22 receives vibration data Dv from the sensor unit 21 at each sampling timing, and stores the received vibration data Dv in chronological order.

The control unit 31 can change the sampling rate of the AD conversion unit 27, that is, the frequency of the clock signal in the clock generation unit 28. More specifically, the control unit 31 can change the sampling rate of the AD conversion unit 27 in 10 steps of R1 to R10 in ascending order. The control unit 31 may be able to change the sampling rate of the AD conversion unit 27 to 2 to 9 stages or 11 stages or more.

For example, when a predetermined initialization condition is satisfied, the control unit 31 performs a process of determining an optimum sampling rate capable of efficiently sampling the measurement signal Sa.

Here, the initialization condition is, for example, that the own vibration measuring device 101 has transitioned from the off state to the on state. The initialization condition may be that predetermined times such as 1st, 10th, and January have elapsed.

Specifically, the control unit 31 sets the sampling rate of the AD conversion unit 27 to the maximum R10, which is the first rate.

More specifically, the control unit 31 outputs a setting instruction S1 to the effect that the frequency of the clock signal should be set to the first rate to the clock generation unit 28 in the sensor unit 21.

The control unit 31 may be configured to set the value of the clock register described above to the corresponding value instead of outputting the setting instruction S1 to the filter unit 26.

Further, the control unit 31 determines the sampling rate of the AD conversion unit 27, here the cutoff frequency according to R10. Specifically, the control unit 31 determines, for example, the cutoff frequency to be 1/2 of the sampling rate. The cutoff frequency can be set to, for example, 1/10 of the sampling rate.

The control unit 31 outputs a setting command S2 to the effect that the determined cutoff frequency should be set to the filter unit 26 of the sensor unit 21.

The control unit 31 may be configured to set the value of the above-mentioned filter register to the corresponding value instead of outputting the setting instruction S2 to the filter unit 26.

Further, the memory 30 is not limited to the configuration in which the memory 30 receives the vibration data from the sensor unit 21 and stores the received vibration data, and the control unit 31 acquires the vibration data Dv held in the above-mentioned data holding register. It may be configured to be stored in the memory 30.

FIG. 7 is a diagram showing an example of an effective value of acceleration calculated by a control unit in the wireless module according to the first embodiment of the present invention.

With reference to FIG. 7, the control unit 31 changes the sampling rate of the AD conversion unit 27 based on the vibration data Dv created by the AD conversion unit 27.

Specifically, the control unit 31 is, for example, in a state where the AD conversion unit 27 creates the vibration data Dv by sampling at the first rate, and the sampling rate of the AD conversion unit 27 is based on the vibration data Dv. To a second rate that is less than the first rate.

More specifically, the control unit 31 determines the optimum sampling rate based on the vibration data Dv created at the plurality of sampling rates.

Specifically, the control unit 31 calculates, for example, a representative value of each of the vibration data Dv created at a plurality of sampling rates.

More specifically, the control unit 31 calculates the effective value Ae10 of the acceleration at the sampling rate R10 as a representative value at the sampling rate R10.

For example, the control unit 31 monitors the number of vibration data Dv stored in the memory 30, and when the target number of vibration data Dv is stored in the memory 30, the control unit 31 acquires the target number of vibration data Dv from the memory 30. .. Here, the target number is, for example, a value obtained by dividing a predetermined measurement target time by the current sampling rate of the AD conversion unit 27. The target number may be a predetermined value.

The control unit 31 calculates and holds the effective value Ae10 based on the acquired vibration data Dv of the target number.

More specifically, for example, when the target number is N and the values indicated by each of the target number vibration data Dv are represented by X1 to XN, the effective value Ae of the target number vibration data Dv is as follows. It is calculated by the formula (1).

Then, the control unit 31 issues a setting command S1 to the effect that the frequency of the clock signal should be set to R9, which is one step smaller, and a setting command S2 to the effect that the cutoff frequency should be set to the cutoff frequency corresponding to the sampling rate R9. Output to the clock generation unit 28 and the filter unit 26, respectively.

The control unit 31 calculates the effective value Ae9 of the acceleration at the sampling rate R9 as a representative value at the sampling rate R9, as in the case of the sampling rate R10.

When the target number of vibration data Dv corresponding to the sampling rate R9 is stored in the memory 30, the control unit 31 acquires the target number of vibration data Dv from the memory 30 and stores the acquired target number of vibration data Dv in the acquired vibration data Dv. The effective value Ae9 is calculated based on this.

The control unit 31 also calculates the effective acceleration values Ae8 to Ae1 in the same manner when the sampling rates are R8 to R1.

FIG. 8 is a diagram showing an example of a change in the effective value with respect to the sampling rate obtained from the calculation result shown in FIG. 7. In FIG. 8, the vertical axis represents the effective value Ae of acceleration, and the horizontal axis represents the sampling rate.

With reference to FIG. 8, the control unit 31 has, for example, the largest sampling rate among a plurality of sampling rates in which the difference from the representative value corresponding to the next smallest sampling rate is outside the predetermined range E1. The sampling rate is determined as the sampling rate of the AD conversion unit 27.

Specifically, the control unit 31 calculates, for example, the difference between the effective value Ae10 corresponding to the sampling rate R10 and the effective value Ae9 corresponding to the sampling rate R9 having the next smallest value after the sampling rate R10, and the calculated difference. Is within the predetermined range E1.

In this example, the upper limit value and the lower limit value of the predetermined range E1 are positive and negative, respectively, and the absolute value of the upper limit value and the absolute value of the lower limit value are the same. The absolute value of the upper limit and the absolute value of the lower limit of the predetermined range E1 may be different.

Further, when the calculated difference is out of the predetermined range, the difference is larger than the upper limit value or the difference is smaller than the lower limit value.

Similarly, the control unit 31 confirms that the difference between the effective values Ae9 to Ae6 corresponding to the sampling rates R9 to R6 and the effective value Ae corresponding to the next smallest sampling rate is within the predetermined range E1. To do.

On the other hand, the control unit 31 calculates the difference between the effective value Ae5 corresponding to the sampling rate R5 and the effective value Ae4 corresponding to the sampling rate R4 having the next smallest value after the sampling rate R5, and the calculated difference is outside the predetermined range E1. Confirm that.

Similarly, the control unit 31 confirms that the difference between the effective values Ae4 to Ae2 corresponding to the sampling rates R4 to R2 and the effective value Ae corresponding to the next smallest sampling rate is outside the predetermined range E1. To do.

The control unit 31 determines the maximum sampling rate R5 among the sampling rates R5 to R2 whose difference is outside the predetermined range E1 as the optimum sampling rate of the AD conversion unit 27.

The control unit 31 issues a setting command S1 indicating that the frequency of the clock signal should be set to the optimum sampling rate and a setting command S2 indicating that the cutoff frequency should be set according to the optimum sampling rate in the sensor unit 21. Output to 28 and filter unit 26, respectively.

After determining the optimum sampling rate, the control unit 31 acquires the target number of vibration data Dvs from the memory 30 when the target number of vibration data Dvs corresponding to the determined optimum sampling rate is stored in the memory 30.

The control unit 31 creates vibration data information including the target number of vibration data Dvs and the ID of its own wireless module 22, and outputs the created vibration data information to the transmission unit 32.

The control unit 31 is not limited to the configuration in which the optimum sampling rate is determined after all the effective values Ae10 to Ae1 corresponding to the sampling rates R10 to R1 are calculated, and at least two of the effective values Ae10 to Ae1 are calculated. After that, the optimum sampling rate may be determined.

Specifically, the control unit 31 calculates, for example, the effective values Ae10 and Ae9, and determines whether or not the difference between Ae10 and Ae9 is outside the predetermined range E1. When the control unit 31 determines that the difference is within the predetermined range E1, the control unit 31 newly calculates the effective value Ae8 and determines whether or not the difference between the Ae9 and the Ae8 is outside the predetermined range E1.

When the control unit 31 repeats this process and newly calculates the effective value Ae4, the control unit 31 determines that the difference between Ae5 and Ae4 is outside the predetermined range E1. Then, the control unit 31 determines the sampling rate R5 as the optimum sampling rate of the AD conversion unit 27.

With reference to FIG. 6 again, the transmission unit 32 transmits a radio signal including the vibration data Dv by one-way communication. Specifically, the transmission unit 32 can transmit a radio signal according to, for example, the communication standard of IEEE802.1.5.

More specifically, when the transmission unit 32 receives the vibration data information from the control unit 31, for example, the transmission unit 32 divides the received vibration data information into a plurality of packets and stores the received vibration data information in a packet, and sequentially broadcasts the plurality of packets.

After determining the optimum sampling rate, for example, the control unit 31 creates vibration data information each time a target number of vibration data Dvs are stored in the memory 30 and transmits the vibration data information via the transmission unit 32.

Then, for example, after changing to the second rate, that is, the sampling rate R5, the control unit 31 changes the sampling rate of the AD conversion unit 27 to the first rate when the predetermined condition C1 not based on the vibration data is satisfied. .. Here, the predetermined condition C1 is, for example, that a periodic timing has arrived, or that the control unit 31 has received on-operation information from the operation unit 24.

More specifically, the control unit 31 returns the sampling rate of the AD conversion unit 27 to the first rate every predetermined cycle T1 such as every day or every month, and determines the optimum sampling rate. I do.

With reference to FIG. 1 again, the access point 151 transmits the vibration data Dv included in the radio signal received from the radio module 22 in the vibration measuring device 101.

More specifically, each time the access point 151 receives a packet from the vibration measuring device 101, the access point 151 relays the received packet and transmits it to the management device 181 via the internal network 11.

The management device 181 processes the vibration data Dv received from the access point 151. More specifically, when the management device 181 receives a plurality of packets from the access point 151, the management device 181 acquires vibration data information from the received plurality of packets.

The management device 181 performs an analysis process based on the acquired vibration data information. Specifically, the management device 181 extracts the target number of vibration data Dvs from the vibration data information, and indicates the ID of the wireless module 22 included in the vibration data information and the reception time in the extracted target number of vibration data Dvs. Add a time stamp.

The management device 181 derives the vibration status of the equipment 10 by analyzing the vibration data Dv of the target number, and records the derived vibration status in association with the ID of the wireless module 22 and the reception time.

[Modification example of decision processing]
FIG. 9 is a diagram showing an example of a frequency analysis result of vibration data in the wireless module according to the first embodiment of the present invention. In FIG. 9, the vertical axis represents acceleration and the horizontal axis represents frequency.

With reference to FIGS. 6 and 9, as shown in FIGS. 7 and 8, the control unit 31 is configured to determine the optimum sampling rate based on the vibration data Dv created at a plurality of sampling rates. However, it is not limited to this. The control unit 31 may be configured to determine the optimum sampling rate based on the vibration data Dv created at one sampling rate.

More specifically, the control unit 31 sets the sampling rate of the AD conversion unit 27 and the cutoff frequency in the filter unit 26 to the first rate and the frequency corresponding to the first rate, respectively.

Then, when the vibration data Dv of the preset number of samples is stored in the memory 30, the control unit 31 acquires the vibration data Dv of the number of samples from the memory 30. Here, the number of samples is, for example, a number corresponding to a desired frequency resolution and is 2 to the nth power (where n is an integer of 2 or more).

The vibration data Dv of the number of samples shows a time spectrum in which the time interval between sample points is the reciprocal of the first rate.

The control unit 31 creates the frequency spectrum shown in FIG. 9 by performing FFT processing on the time spectrum.

The control unit 31 detects, for example, a peak larger than a predetermined threshold value Th1 in the created frequency spectrum, and identifies the peak P1 having the highest frequency among the detected peaks.

The control unit 31 determines, for example, a frequency obtained by multiplying the frequency F1 corresponding to the peak P1 by 2.56 as the optimum sampling rate.

The control unit 31 issues a setting command S1 indicating that the frequency of the clock signal should be set to the optimum sampling rate and a setting command S2 indicating that the cutoff frequency should be set according to the optimum sampling rate in the sensor unit 21. Output to 28 and filter unit 26, respectively.

The control unit 31 is configured to determine the optimum sampling rate based on the peak P1 having the highest frequency among the detected peaks, but the present invention is not limited to this. The control unit 31 may be configured to determine the optimum sampling rate based on the peak with the highest intensity among the detected peaks.

Specifically, the control unit 31 identifies the peak P2 having the highest intensity among the detected peaks, and determines the frequency obtained by multiplying the frequency F2 corresponding to the peak P2 by 2.56 as the optimum sampling rate. ..

[Variation example of vibration measuring device 101]
FIG. 10 is a diagram showing a configuration of a modified example of a vibration measuring device in the vibration sensor system according to the first embodiment of the present invention.

With reference to FIG. 10, a modified example of the vibration measuring device 101 further includes a power supply management unit 33 as compared with the vibration measuring device 101 shown in FIG.

The operations of the sensor unit 21, the wireless module 22, the battery 23, and the operation unit 24 in the modified example of the vibration measurement device 101 are the operation of the sensor unit 21, the wireless module 22, the battery 23, and the operation unit 24 in the vibration measurement device 101 shown in FIG. The same is true for each.

The power management unit 33 in the modified example of the vibration measuring device 101 controls on and off of the power supply to the sensor unit 21 and the wireless module 22.

More specifically, the power management unit 33 is set with, for example, a schedule in which the wake-up period and the sleep period are alternately repeated. The power management unit 33 controls the on / off of the power supply to the sensor unit 21 and the wireless module 22 according to the schedule.

The power management unit 33 supplies the electric power from the battery 23 to the sensor unit 21 and the wireless module 22 during the wake-up period. On the other hand, the power management unit 33 stops the power supply to the sensor unit 21 and the wireless module 22 during the sleep period.

The sensor unit 21 and the wireless module 22 start operating when the power supply management unit 33 receives power during the wake-up period.

The wireless module 22 determines the optimum sampling rate, and sets the sampling rate of the AD conversion unit 27 in the sensor unit 21 and the cutoff frequency in the filter unit 26 to the optimum sampling rate and the frequency corresponding to the optimum sampling rate, respectively.

The wireless module 22 receives the vibration data Dv from the sensor unit 21 and broadcasts the vibration data information including the received vibration data Dv.

When the sensor unit 21 and the wireless module 22 enter the sleep period and the power supply from the power management unit 33 is stopped, the operation of the sensor unit 21 and the wireless module 22 is stopped.

The power management unit 33 monitors the transmission operation of the wireless module 22, and when the transmission operation of the wireless module 22 ends before the start timing of the sleep period, the transmission is performed even if the timing is before the start timing. The power supply to the sensor unit 21 and the wireless module 22 may be stopped after the operation is completed.

[Operation flow]
Each device in the vibration sensor system 301 includes a computer, and an arithmetic processing unit such as a CPU in the computer reads a program including a part or all of each step of the following sequence diagram or flowchart from a memory (not shown) and executes the program. To do. The programs of these plurality of devices can be installed from the outside. The programs of these plurality of devices are distributed in a state of being stored in a recording medium.

FIG. 11 is a flowchart defining an operation procedure when the vibration sensor system according to the first embodiment of the present invention processes vibration data.

With reference to FIG. 11, it is assumed that power is not supplied to the vibration measuring device 101.

First, the vibration measuring device 101 remains in the off state until the initialization condition is satisfied, that is, until power is supplied to itself (NO in step S102).

Then, when the vibration measuring device 101 is supplied with electric power (YES in step S102), the vibration measuring device 101 performs a process of determining the optimum sampling rate (step S104).

Next, the vibration measuring device 101 sets the sampling rate in the AD conversion unit 27 and the cutoff frequency in the filter unit 26 to the optimum sampling rate and the frequency corresponding to the optimum sampling rate, respectively (step S106).

Next, the vibration measuring device 101 creates vibration data Dv at the optimum sampling rate (step S108).

Next, the vibration measuring device 101 transmits the vibration data information including the created vibration data Dv to the management device 181 via the access point 151 and the internal network 11 (step S110).

Next, when the management device 181 receives the vibration data information from the vibration measuring device 101, the management device 181 performs an analysis process based on the received vibration data information (step S112).

Next, when the predetermined condition C1 is satisfied (YES in step S114), the vibration measuring device 101 performs the optimum sampling rate determination process (step S104).

On the other hand, when the predetermined condition C1 is not satisfied (NO in step S114), the vibration measuring device 101 creates vibration data Dv at the optimum sampling rate (step S108).

The vibration measuring device 101 has determined in step S114 whether or not the predetermined condition C1 is satisfied, but the present invention is not limited to this. The vibration measuring device 101 may perform the determination as an interrupt process in any of steps S106 and S108, between steps S108 and S110, and between steps S110 and S112.

FIG. 12 is a flowchart defining an operation procedure when the vibration sensor system according to the first embodiment of the present invention performs the optimum sampling rate determination process. FIG. 12 shows the details of the operation in step S104 of FIG.

With reference to FIG. 12, first, the vibration measuring device 101 sets the sampling rate in the AD conversion unit 27 and the cutoff frequency in the filter unit 26 to R10 and frequencies corresponding to R10, respectively (step S202).

Next, the vibration measuring device 101 creates vibration data Dv at the sampling rate R10 (step S204).

Next, the vibration measuring device 101 calculates the effective value Ae10 based on the created vibration data Dv (step S206).

Next, the vibration measuring device 101 lowers the sampling rate in the AD conversion unit 27 by one step and sets it to R9, and sets the cutoff frequency in the filter unit 26 to a frequency corresponding to R9 (step S208).

Next, the vibration measuring device 101 creates vibration data Dv at the set sampling rate (step S210).

Next, the vibration measuring device 101 calculates the effective value Ae based on the created vibration data Dv (step S212).

Next, the vibration measuring device 101 calculates the difference between the effective value Ae immediately before the sampling rate is lowered by one step and the effective value Ae after the sampling rate is lowered by one step (step S214).

Next, when the calculated difference is within the predetermined range E1 (NO in step S216), the vibration measuring device 101 sets the sampling rate in the AD conversion unit 27 to a value further lowered by one step, and sets the sampling rate in the filter unit 26 to a value further lowered. The cutoff frequency is set to a frequency corresponding to the lowered sampling rate (step S208).

On the other hand, when the calculated difference is outside the predetermined range E1 (YES in step S216), the vibration measuring device 101 determines the sampling rate immediately before lowering the sampling rate by one step as the optimum sampling rate (step S218).

The vibration sensor system according to the first embodiment of the present invention includes, but is not limited to, a plurality of vibration measuring devices 101, a plurality of access points 151, and a management device 181. .. The vibration sensor system 301 achieves the object of the present invention of efficiently sampling the measurement result of the vibration in the configuration for measuring the vibration of the measurement target by the minimum component including the AD conversion unit 27 and the control unit 31. It is possible to do.

Further, the vibration sensor system according to the first embodiment of the present invention is configured to be provided with a plurality of vibration measuring devices 101, but the present invention is not limited to this. The vibration sensor system 301 may be configured to be provided with one vibration measuring device 101.

Further, in the vibration sensor system according to the first embodiment of the present invention, the sensor 25 is configured to measure the acceleration of the measurement target, but the present invention is not limited to this. The sensor 25 may be configured to measure either the position or the speed of the measurement target. Even when the vibration data Dv indicates the position or speed of the measurement target, it is possible to calculate the optimum sampling rate based on the vibration data.

Further, in the vibration sensor system according to the first embodiment of the present invention, the sensor 25 is provided, but the present invention is not limited to this. The sensor 25 may be provided outside the vibration sensor system 301.

Further, in the vibration sensor system according to the first embodiment of the present invention, the control unit 31 sets the sampling rate in a state where the AD conversion unit 27 creates vibration data Dv by sampling at the first rate. The configuration is such that the rate is changed to a second rate, which is smaller than the first rate, but the present invention is not limited to this. The control unit 31 has a configuration in which the sampling rate is changed to a first rate larger than the second rate in a state where the AD conversion unit 27 creates vibration data Dv by sampling at the second rate. May be good.

Further, in the vibration sensor system according to the first embodiment of the present invention, the control unit 31 changes the sampling rate to the first rate when the predetermined condition C1 is satisfied after the change to the second rate. Although it is said that the configuration has a function, the configuration is not limited to this. The control unit 31 may have a configuration that does not have the function.

Further, in the vibration sensor system according to the first embodiment of the present invention, the predetermined condition C1 is that the periodic timing has arrived or the control unit 31 has received the on-operation information from the operation unit 24. However, it is not limited to this. The predetermined condition C1 may be either the arrival of periodic timing or the reception of on-operation information from the operation unit 24 by the control unit 31.

Further, in the vibration sensor system according to the first embodiment of the present invention, the transmission unit 32 is configured to perform one-way communication, but the present invention is not limited to this. The transmission unit 32 may be configured to perform two-way communication. As a result, the transmission unit 32 can receive, for example, an ACK for confirmation of reception and a request for retransmission of the missing vibration data Dv from the management device 181. Therefore, the transmission unit 32 can communicate between the vibration measurement device 101 and the management device 181. Reliability can be increased.

By the way, beyond the technique described in Patent Document 1 described above, there is a demand for a technique for efficiently sampling analog measurement results for vibration of a measurement target.

On the other hand, in the vibration sensor system according to the first embodiment of the present invention, the AD conversion unit 27 samples the measurement result of the sensor that measures the vibration of the measurement target and creates the vibration data Dv. Then, the control unit 31 changes the sampling rate of the AD conversion unit 27 based on the vibration data Dv created by the AD conversion unit 27.

With such a configuration, the vibration state of the measurement target can be grasped based on the vibration data Dv, so that an appropriate sampling rate can be obtained. As a result, for example, the sampling rate of the AD conversion unit 27 can be changed to a sampling rate according to the vibration condition of the measurement target. Therefore, since the sampling rate is faster than necessary, the vibration data Dv to be continuously sampled It is possible to prevent the amount from increasing and the memory capacity to be prepared for holding the sampled vibration data Dv from increasing. In addition, it is possible to prevent an increase in power consumption due to a sampling rate that is faster than necessary. Therefore, in the configuration for measuring the vibration of the measurement target, the measurement result of the vibration can be efficiently sampled.

Further, in the vibration sensor system according to the first embodiment of the present invention, the control unit 31 is in a state where the AD conversion unit 27 creates the vibration data Dv by sampling at the first rate, and the vibration data Dv. Based on, the sampling rate is changed to a second rate that is smaller than the first rate.

With such a configuration, the presence or absence of a higher frequency vibration component can be grasped based on the vibration data of the larger first rate, so that a more appropriate second rate can be obtained.

Further, in the vibration sensor system according to the first embodiment of the present invention, when the control unit 31 satisfies the predetermined condition C1 not based on the vibration data Dv after the change to the second rate, the sampling rate is set to the second. Change to a rate of 1.

In this way, when the predetermined condition C1 is satisfied, the configuration for returning the second rate to the first rate makes it possible to grasp the changed vibration state even when the vibration state of the measurement target changes, for example. Therefore, it is possible to obtain the sampling rate according to the change in the vibration condition.

Further, in the vibration sensor system according to the first embodiment of the present invention, the predetermined condition C1 is the arrival of a periodic timing.

In this way, by periodically returning the second rate to the first rate, for example, even when the change in the vibration condition of the measurement target cannot be predicted, it is possible to deal with the change in the vibration condition with a simple configuration. it can.

Further, in the vibration sensor system according to the first embodiment of the present invention, the operation unit 24 is used to return the sampling rate to the first rate.

With such a configuration, for example, when the user recognizes that the vibration condition of the measurement target has changed, the user can return the second rate to the first rate by operating the operation unit 24. ..

Further, in the vibration sensor system according to the first embodiment of the present invention, the control unit 31 calculates a representative value of each of the vibration data Dv created at a plurality of sampling rates. Then, the control unit 31 sets the maximum sampling rate among the plurality of sampling rates whose difference from the representative value corresponding to the next smallest sampling rate is outside the predetermined range E1 to the AD conversion unit 27. Determined as the sampling rate of.

With such a configuration, for example, the sampling rate can be determined without performing the FFT process, so that the process in the control unit 31 can be simplified.

Further, in the vibration sensor system according to the first embodiment of the present invention, the radio module 22 transmits a radio signal including vibration data Dv. The access point 151 transmits the vibration data Dv included in the radio signal received from the radio module 22. The management device 181 processes the vibration data Dv received from the access point 151. The wireless module 22 includes a control unit 31.

In this way, with the configuration in which the wireless module 22 includes the control unit 31, for example, the vibration data Dv created by the AD conversion unit 27 after the control unit 31 changes the sampling rate in the AD conversion unit 27 to an appropriate sampling rate. Can be transmitted by the wireless module 22. As a result, it is possible to prevent the vibration data Dv having a data length longer than necessary from being wirelessly transmitted, so that the power consumption of the wireless module 22 can be suppressed. In addition, it is possible to reduce the possibility that vibration data Dv is missing in wireless transmission. Therefore, for example, in a configuration in which the wireless module 22 can perform bidirectional communication, the frequency of retransmitting the missing vibration data Dv can be reduced.

Further, in the vibration sensor system according to the first embodiment of the present invention, the wireless module 22 transmits a wireless signal by one-way communication.

Such a configuration can simplify the functions and processing of the wireless module 22. Further, since the wireless module 22 does not need to listen for a wireless signal from another device such as the access point 151, the wireless module 22 can be turned off, for example, during the period when the wireless module 22 does not transmit the wireless signal. As a result, the power consumption of the wireless module 22 can be suppressed.

Next, other embodiments of the present invention will be described with reference to the drawings. The same or corresponding parts in the drawings are designated by the same reference numerals, and the description thereof will not be repeated.

<Second embodiment>
The present embodiment relates to a vibration sensor system in which an optimum sampling rate is determined in a management device as compared with the vibration sensor system according to the first embodiment. It is the same as the vibration sensor system according to the first embodiment except for the contents described below.

[Configuration and basic operation]
FIG. 13 is a diagram showing a configuration of a vibration sensor system according to a second embodiment of the present invention.

With reference to FIG. 13, the vibration sensor system 302 includes a plurality of vibration measuring devices 102, an access point (wireless master unit) 151, and a management device 182.

The operation of the access point 151 in the vibration sensor system 302 is the same as that of the access point 151 in the vibration sensor system 301 shown in FIG.

The vibration measuring device 102 has a function of transmitting and receiving information by wireless communication, and can communicate with the management device 182 via the access point 151 and the internal network 11.

FIG. 14 is a diagram showing a configuration of a vibration measuring device in the vibration sensor system according to the second embodiment of the present invention.

With reference to FIG. 14, the vibration measuring device 102 includes a wireless module (wireless slave unit) 52 instead of the wireless module 22 as compared with the vibration measuring device 101 shown in FIG.

The operations of the sensor unit 21, the battery 23, and the operation unit 24 in the vibration measuring device 102 are the same as those of the sensor unit 21, the battery 23, and the operating unit 24 in the vibration measuring device 101 shown in FIG.

FIG. 15 is a diagram showing a configuration of a wireless module in the vibration measuring device according to the second embodiment of the present invention.

With reference to FIG. 15, the wireless module 52 includes a processing unit 61 and a communication unit 62 instead of the control unit 31 and the transmitting unit 32 as compared with the wireless module 22 shown in FIG.

The operation of the memory 30 in the wireless module 52 is the same as that of the memory 30 in the wireless module 22 shown in FIG.

The processing unit 61 outputs reset information to the communication unit 62, for example, when the above-mentioned initialization conditions are satisfied.

The communication unit 62 can perform bidirectional wireless communication with the access point 151. When the communication unit 62 receives the reset information from the processing unit 61, the communication unit 62 transmits the received reset information to the management device 182 via the access point 151 and the internal network 11.

FIG. 16 is a diagram showing a configuration of a management device in the vibration sensor system according to the second embodiment of the present invention.

With reference to FIG. 16, the management device 182 includes a memory 70, a control unit 71, a communication unit 72, and an analysis unit 73.

The communication unit 72 can communicate with the access point 151 via the internal network 11.

When the communication unit 72 receives the reset information from the vibration measuring device 102, the communication unit 72 outputs the received reset information to the control unit 71.

Upon receiving the reset information from the communication unit 72, the control unit 71 performs a process of determining the optimum sampling rate.

Specifically, the control unit 71 has a setting instruction S1 indicating that the frequency of the clock signal in the clock generation unit 28 (see FIG. 5) should be set to the first rate, and a cutoff frequency corresponding to the first rate. The setting command S2 to the effect that it should be set to is transmitted to the vibration measuring device 102 via the communication unit 72, the internal network 11, and the access point 151.

With reference to FIG. 15 again, when the processing unit 61 in the wireless module 52 receives the setting instructions S1 and S2 from the management device 182 via the communication unit 62, the processing unit 61 transmits the received setting instructions S1 and S2 to the clock generation unit 28 and the filter unit. Output to 26 respectively.

For example, the processing unit 61 monitors the number of vibration data Dvs stored in the memory 30, and when the target number of vibration data Dvs corresponding to the first rate indicated by the setting command S1 is stored in the memory 30, the said The target number of vibration data Dvs are acquired from the memory 30.

The processing unit 61 creates vibration data information including the acquired number of target vibration data Dvs and the ID of its own wireless module 52, and transmits the created vibration data information via the communication unit 62, the access point 151, and the internal network 11. It is transmitted to the management device 182.

With reference to FIG. 16 again, when the control unit 71 in the management device 182 receives the vibration data information from the vibration measurement device 102 via the communication unit 72, the control unit 71 holds the received vibration data information in the memory 70 and the vibration data information. The effective value Ae10 is calculated based on.

Then, the control unit 71 issues a setting instruction S1 to the effect that the frequency of the clock signal should be set to R9 and a setting instruction S2 to the effect that the cutoff frequency should be set according to R9, as in the case of the sampling rate R10. The frequency is transmitted to the vibration measuring device 102 via the communication unit 72, the internal network 11, and the access point 151.

When the control unit 71 receives vibration data information from the vibration measuring device 102 via the communication unit 72 as a response to the setting commands S1 and S2, the control unit 71 holds the received vibration data information in the memory 70 and is based on the vibration data information. The effective value Ae9 is calculated.

Similarly, the control unit 71 calculates the effective acceleration values Ae8 to Ae1 when the sampling rates are R8 to R1.

The control unit 71 sets the maximum sampling rate among the sampling rates R10 to R1 as the optimum sampling rate among the sampling rates whose difference from the effective value Ae corresponding to the next smallest sampling rate is outside the predetermined range E1. decide.

The control unit 71 issues a setting command S1 to the effect that the optimum sampling rate is set to the determined optimum sampling rate and a setting instruction S2 to the effect that the cutoff frequency should be set to the optimum sampling rate determined by the communication unit 72, the internal network 11, and the access point. It is transmitted to the vibration measuring device 102 via 151.

When the control unit 71 receives vibration data information from the vibration measuring device 102 via the communication unit 72 as a response to the setting commands S1 and S2, the control unit 71 holds the received vibration data information in the memory 70 and analyzes the vibration data information. Output to unit 73.

When the analysis unit 73 receives the vibration data information from the control unit 71, the analysis unit 73 performs an analysis process based on the received vibration data information.

With reference to FIG. 15 again, when the predetermined condition C1 is satisfied, the processing unit 61 in the wireless module 52 transmits the reset information to the management device 182 via the communication unit 62, the access point 151, and the internal network 11.

In the vibration sensor system according to the second embodiment of the present invention, the operation unit 24 is configured to be provided in the vibration measuring device 102, but the present invention is not limited to this. The operation unit 24 may be configured to be provided in the management device 182.

As described above, in the vibration sensor system according to the second embodiment of the present invention, the radio module 52 transmits a radio signal including vibration data Dv. The access point 151 transmits the vibration data Dv included in the radio signal received from the radio module 52. The management device 182 processes the vibration data Dv received from the access point 151. The management device 182 includes a control unit 71.

In this way, the configuration of the management device 182 including the control unit 71 can simplify the configuration of the wireless module 52, for example. Further, for example, when a plurality of AD conversion units 27 are provided in the vibration sensor system 302, the management device 182 can comprehensively process the vibration data Dv created by each AD conversion unit 27, so that each measurement can be performed. The sampling rate of each AD conversion unit 27 can be changed while considering the vibration state at the site.

Since other configurations and operations are the same as those of the vibration sensor system according to the first embodiment, detailed description will not be repeated here.

It is also possible to appropriately combine some or all of the components and operations of the devices according to the first embodiment and the second embodiment of the present invention.

It should be considered that the above embodiments are exemplary in all respects and not restrictive. The scope of the present invention is shown by the scope of claims rather than the above description, and is intended to include all modifications within the meaning and scope equivalent to the scope of claims.

The above description includes the features described below.

[Appendix 1]
A data creation unit that creates vibration data by sampling the measurement results of the sensor that measures the vibration of the measurement target,
A control unit that changes the sampling rate of the data creation unit based on the vibration data created by the data creation unit is provided, and the measurement target is equipment including a rotating unit.
The sensor is an acceleration sensor and is attached so as to be in close contact with the equipment.
The sensor measures its own acceleration as the acceleration of the equipment, and outputs an analog measurement signal indicating the measurement result to the data creation unit.
The data creation unit creates the vibration data by sampling the measurement signal received from the sensor.
The vibration sensor system further
A filter unit for digitally filtering the vibration data created by the data creation unit is provided.
The control unit creates a frequency spectrum by performing FFT (Fast Fourier Transform) processing on the vibration data digitally filtered by the filter unit, and based on the created frequency spectrum, the sampling rate of the data creation unit. To change the vibration sensor system.

9 Rotating part 10 Equipment 11 Internal network 21 Sensor part 22 Wireless module (wireless slave unit)
23 Battery 24 Operation unit 25 Sensor 26 Filter unit 27 AD conversion unit (data creation unit)
28 Clock generator 30 Memory 31 Control unit 32 Transmitter 33 Power management unit 52 Wireless module (wireless slave unit)
61 Processing unit 62 Communication unit 70 Memory 71 Control unit 72 Communication unit 73 Analysis unit 101,102 Vibration measuring device 151 Access point (wireless master unit)
181,182 Management device 301,302 Vibration sensor system

Claims (11)

A data creation unit that creates vibration data by sampling the measurement results of the sensor that measures the vibration of the measurement target,
A vibration sensor system including a control unit that changes the sampling rate of the data creation unit based on the vibration data created by the data creation unit. In a state where the data creation unit creates the vibration data by sampling at the first rate, the control unit sets the sampling rate to be smaller than the first rate based on the vibration data. The vibration sensor system according to claim 1, wherein the rate is changed to. The vibration sensor system according to claim 2, wherein the control unit changes the sampling rate to the first rate when a predetermined condition not based on the vibration data is satisfied after the change to the second rate. .. The vibration sensor system according to claim 3, wherein the predetermined condition is the arrival of periodic timing. The vibration sensor system further
The vibration sensor system according to any one of claims 2 to 4, further comprising an operation unit for returning the sampling rate to the first rate. The control unit calculates a representative value of each of the vibration data created at the plurality of sampling rates, and sets the representative value corresponding to the sampling rate having the next smallest value among the plurality of sampling rates. The vibration sensor system according to any one of claims 1 to 5, wherein the maximum sampling rate among the sampling rates whose difference is outside the predetermined range is determined as the sampling rate of the data creation unit. The vibration sensor system further
A wireless slave unit that transmits a wireless signal containing the vibration data, and
A wireless master unit that transmits the vibration data included in the wireless signal received from the wireless slave unit, and
A management device for processing the vibration data received from the wireless master unit is provided.
The vibration sensor system according to any one of claims 1 to 6, wherein the wireless slave unit includes the control unit. The vibration sensor system according to claim 7, wherein the wireless slave unit transmits the wireless signal by one-way communication. The vibration sensor system further
A wireless slave unit that transmits a wireless signal containing the vibration data, and
A wireless master unit that transmits the vibration data included in the wireless signal received from the wireless slave unit, and
A management device for processing the vibration data received from the wireless master unit is provided.
The vibration sensor system according to any one of claims 1 to 6, wherein the management device includes the control unit. This is a vibration measurement method in a vibration sensor system.
Steps to create vibration data by sampling the measurement results of the sensor that measures the vibration of the measurement target,
A vibration measurement method including a step of changing the sampling rate of the measurement result based on the created vibration data. A vibration measurement program used in vibration sensor systems.
Computer,
A data creation unit that creates vibration data by sampling the measurement results of the sensor that measures the vibration of the measurement target,
A control unit that changes the sampling rate of the data creation unit based on the vibration data created by the data creation unit.
Vibration measurement program to function as.

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