KR102305820B1 - DAQ board for AET system with power consumption reduction function - Google Patents

Abstract

The present invention relates to a DAQ board for an acoustic emission testing (AET) system having a power consumption reduction function for reducing power consumption of the DAQ board under an unnecessary situation that an AE sensor signal input to the DAQ board is absent or a situation of a signal weak which is not worth being analyzed by switching the DAQ board to be in a sleep mode, and for reducing an amount of heat emitted from the DAQ board due to standby power, when an AE sensor signal input to the DAQ board is absent or when the AE sensor signal input to the DAQ board is a signal too weak or almost a noise signal, which is not worth being analyzed, under the environment that an intermittent acoustic emission (AE) sensor signal, which is a signal provided by the AE sensor or provided by a pre-amplifier for the AE sensor, is present. The DAQ board includes: a signal input terminal (100), a gain adjusting module (200), a filter module (300), a buffer driver module (400), an A/D converter module (500), a digital signal processing (DSP) module (600), and a mode control module (700).

Description

DAQ board for AET system with power consumption reduction function {DAQ board for AET system with power consumption reduction function}

The present invention relates to a DAQ board for an AET system having a power consumption reduction function, and more particularly, an intermittent AE (Acoustic Emission) sensor signal (a signal provided by an AE sensor or a signal provided by a preamplifier for an AE sensor) In the existing environment, if there is no AE sensor signal input to the DAQ board, or if the AE sensor signal input to the DAQ board is a signal with no meaning for analysis (too weak or mostly noise signals), put the DAQ board to sleep. By switching to Sleep Mode, it reduces the power consumption of the DAQ board in unnecessary situations (there is no AE sensor signal input to the DAQ board, or a weak state with no meaning for analysis) and reduces the amount of heat generated by the DAQ board due to standby power. It relates to a DAQ board for an AET system having a power consumption saving function to reduce it.

As rapid industrialization and urbanization are progressing around the world, the number of large-scale industrial facilities based on efficient energy distribution is increasing significantly.

However, there are growing concerns about the stability of industrial facilities. In fact, when defects occur in the internal structures of industrial facilities that are concealed from the outside, it is difficult to find them, and there is a high possibility that it can lead to serious problems.

Accordingly, various defect diagnosis technologies are being developed as part of an effort to initially detect various defects such as micro-deformation and micro-cracks in internal structures for industrial facilities. A 'nondestructive inspection' that can diagnose is attracting attention.

'Non-destructive inspection method' is a method of investigating and judging whether a material is incomplete without inflicting additional damage by using the physical phenomenon of the material. etc. are included in this.

However, since most non-destructive testing methods apply direct and one-time energy to the object to inspect for defects, it is difficult to apply to the internal structures of industrial facilities with limited access, and it is difficult to obtain other than the inspection results at a specific point in time, making real-time detection impossible.

On the other hand, the recently known 'non-destructive inspection method using acoustic emission signal (AE)' uses an acoustic emission signal (AE) of a specific frequency band among elastic waves accompanying deformation or cracking of an object to determine whether there are any defects. to judge

'Non-destructive inspection method using acoustic emission signal (AE)' is strictly a non-destructive inspection method in the ultrasonic field, but it has relatively high sensitivity and continuous inspection is possible, and it is not limited by the structure, defect size, direction, etc. Applicable even when access is restricted.

'Non-destructive testing method using acoustic emission signal (AE)' provides the AE sensor signal generated from the AE sensor to the DAQ board for signal processing. Even when there is no signal (weak or mixed with a lot of noise), the conventional DAQ board continues to operate, so it is impossible to design a low-power system.

In addition, the QAD board is a circuit board designed with various circuits and operates sensitively to heat. Under normal circumstances (when the AE signal strength is of a size that has meaning for analysis), heat is generated (the heat is generated due to the operation power applied to the board). Even in situations where it should operate even if it occurs), but it does not need to operate (when there is no AE signal, the AE signal strength is too small, or there is a lot of noise, so there is no meaning in analysis), conventionally, the operating power is applied, resulting in unnecessary waste of energy, Due to this, there was a problem that unnecessary heat was generated in the DAQ board.

In particular, when the PC with the built-in DAQ board is installed in a heat-sensitive environment, for example, in an explosion-proof area of a chemical plant, the heat output inside the PC with the built-in DAQ board increases due to the above problems. There was a ventilation problem due to PC heat.

Accordingly, the present invention provides an AE sensor signal input to the DAQ board in an environment in which intermittent acoustic emission (AE) sensor signals (either a signal provided by an AE sensor or a signal provided by a preamplifier for an AE sensor) exist. If the AE sensor signal input to the board is a signal that has no meaning for analysis (if it is too weak or most of it is a noise signal), switch the DAQ board to sleep mode to make unnecessary situations (AE input to the DAQ board) We propose a technology to reduce the power consumption of the DAQ board when there is no sensor signal or the weak state with no meaning of analysis) and to reduce the amount of heat generated by the DAQ board due to standby power.

(Prior Literature) Korean Patent Application Laid-Open No. 10-2011-0060703

Accordingly, the present invention has been proposed in view of the problems of the prior art as described above, and a first object of the present invention is to provide an AE sensor signal input to the DAQ board in an environment in which intermittent acoustic emission (AE) sensor signals are present. , When the AE sensor signal input to the DAQ board is a signal that has no meaning for analysis (if it is too weak or almost mostly a noise signal), it puts the DAQ board into sleep mode to reduce power consumption due to standby power. have.

In addition, the second object of the present invention is an unnecessary situation in which there is no AE sensor signal input to the DAQ board or the AE sensor signal input to the DAQ board is a signal meaningless of analysis (if it is too weak or most of it is a noise signal) By reducing the amount of heat generated by the standby power of the DAQ board itself, it is possible to reduce the amount of heat generated inside the PC with the built-in DAQ board.

In order to achieve the problem to be solved by the present invention, a DAQ board for an AET system having a power consumption reduction function,

a signal input terminal 100 to which an acoustic wave signal that is an AE (Acoustic Emission) signal is input from the external sensor amplifier 1;

a gain adjustment module 200 for amplifying or attenuating the acoustic wave signal input through the signal input terminal 100;

a filter module 300 for removing unnecessary frequency band noise components included in the amplified or attenuated acoustic wave signal;

a buffer driver module 400 that provides the acoustic wave signal from which the noise component has been removed to the A/D converter module;

an A/D converter module 500 for converting an acoustic wave signal that is an analog signal provided by the buffer driver module 400 into a digital signal;

a DSP module 600 for providing an acoustic wave signal converted into a digital signal to an external analysis device 2;

A mode control module that uses the acoustic wave signal input through the signal input terminal 100 to operate the DAQ board in the sleep mode or operation mode, thereby reducing the power consumption of the DAQ board in the standby state to reduce the amount of heat generated by the DAQ board. (700);

Through the DAQ board for an AET system having a power consumption reduction function according to the present invention having the above configuration and operation, in an environment where intermittent AE (Acoustic Emission) sensor signals exist, there is no AE sensor signal input to the DAQ board, If the AE sensor signal input to the DAQ board is a signal that has no meaning for analysis (if it is too weak or mostly noise signals), put the DAQ board into sleep mode to reduce power consumption due to standby power. will perform

In addition, the standby power of the DAQ board itself in unnecessary situations where there is no AE sensor signal input to the DAQ board or the AE sensor signal input to the DAQ board is a meaningless signal (if it is too weak or mostly noise signals). By reducing the amount of heat generated by the DAQ board, it is possible to reduce the amount of heat generated inside the PC where the DAQ board is installed.

Therefore, when the AET System is installed in an environment such as an explosion-proof area of a chemical plant, it is effective to solve the ventilation problem caused by PC heat.

1 is a conceptual configuration diagram of a DAQ board for an AET system having a power consumption reduction function according to an embodiment of the present invention.
2 is a block diagram of a DAQ board for an AET system having a power consumption reduction function according to the first embodiment of the present invention.
3 is a block diagram of a DAQ board for an AET system having a power consumption reduction function according to a second embodiment of the present invention.
4 is an operation example of a timer unit 730 of a DAQ board for an AET system having a power consumption reduction function according to a second embodiment of the present invention.
5 is an operation example of the timer unit 730 of the DAQ board for an AET system having a power consumption reduction function according to the second embodiment of the present invention.

The following is merely illustrative of the principles of the invention. Therefore, those skilled in the art will be able to devise various devices which, although not explicitly described or shown herein, embody the principles of the present invention and are included within the spirit and scope of the present invention.

In addition, it should be understood that all conditional terms and examples listed herein are, in principle, expressly intended only for the purpose of understanding the inventive concept and are not limited to the specifically enumerated embodiments and states as such. do.

Means for solving the problems of the present invention are as follows.

That is, the DAQ board for the AET system having the power consumption reduction function of the present invention,

a signal input terminal 100 to which an acoustic wave signal that is an AE (Acoustic Emission) signal is input from the external sensor amplifier 1;

a gain adjustment module 200 for amplifying or attenuating the acoustic wave signal input through the signal input terminal 100;

a filter module 300 for removing unnecessary frequency band noise components included in the amplified or attenuated acoustic wave signal;

a buffer driver module 400 that provides the acoustic wave signal from which the noise component has been removed to the A/D converter module;

an A/D converter module 500 for converting an acoustic wave signal that is an analog signal provided by the buffer driver module 400 into a digital signal;

a DSP module 600 for providing an acoustic wave signal converted into a digital signal to an external analysis device 2;

A mode control module that uses the acoustic wave signal input through the signal input terminal 100 to operate the DAQ board in the sleep mode or operation mode, thereby reducing the power consumption of the DAQ board in the standby state to reduce the amount of heat generated by the DAQ board. (700);

The mode control module 700 according to the first embodiment of the present invention,

a DC removing unit 710 that removes a DC component included in the input acoustic wave signal and provides it to the trigger unit 720 to remove primary noise included in the acoustic wave signal input through the signal input terminal 100;

It is determined whether the lowest value of the acoustic wave signal from which the DC component is removed and the primary noise has been removed is equal to or greater than a threshold value, and if the lowest value is equal to or greater than the threshold value, the first signal is provided to the switch control unit 740 , and if the lowest value is less than the threshold value, the switch control unit 740 ) and a trigger unit 720 for providing a second signal,

When the first signal is provided from the trigger unit 720, an 'ON' control signal is provided to the power control switch 750, and when the second signal is provided from the trigger unit 720, the power control switch 750 is 'OFF' a switch control unit 740 that provides a control signal; and

When an 'ON' control signal is provided, it is switched to 'ON', so that the power supply that causes the DAQ board to operate in operation mode is provided. It is characterized in that it includes a power control switch 750 to make the power supply to operate.

In addition, the mode control module 700 according to the second embodiment,

a DC removing unit 710 that removes a DC component included in the input acoustic wave signal and provides it to the trigger unit 720 to remove primary noise included in the acoustic wave signal input through the signal input terminal 100;

It is determined whether the lowest value of the acoustic wave signal from which the DC component is removed and the primary noise has been removed is equal to or greater than a threshold value, and if the lowest value is equal to or greater than the threshold value, a trigger signal is provided to the timer unit 740, and if the lowest value is less than the threshold value, the timer unit 740 and a trigger unit 720 that does not provide a trigger signal to

Using whether the trigger unit 720 provides a trigger signal and whether the time count ends, the switch control unit transmits a first signal for enabling the DAQ board to operate in the operation mode or a second signal for enabling the DAQ board to operate in a sleep mode. A timer unit 730 provided as a 740, and

When the first signal is provided from the timer unit 730 , an 'ON' control signal is provided to the power control switch 750 , and when the second signal is provided from the timer unit 730 , the power control switch 750 is 'OFF' a switch control unit 740 that provides a control signal; and

When an 'ON' control signal is provided, it is switched to 'ON', so that the power supply that causes the DAQ board to operate in operation mode is provided. It is characterized in that it includes a power control switch 750 to make the power supply to operate.

The timer unit 730 according to the second embodiment,

For a preset time, count the time,

When the trigger signal is provided in the state where the time count is finished, the first signal is provided to the switch control unit 740 at the same time as the time count is started,

If a trigger signal is provided during time counting, the counted time is reset to start time counting again,

When the trigger signal is not provided in the state where the time count is finished, the second signal is provided to the switch control unit 740 .

Hereinafter, an embodiment of a DAQ board for an AET system having a power consumption reduction function according to the present invention will be described in detail.

1 is a conceptual configuration diagram of a DAQ board for an AET system having a power consumption reduction function according to an embodiment of the present invention.

As shown in FIG. 1 , in the AET system having a power consumption saving function described in the present invention, an AE sensor that provides an AE signal (acoustic wave signal) for a diagnosis object to the preamplifier 1, and an AE provided from the AE sensor A preamplifier 1 for amplifying a signal (acoustic wave signal), and a DAQ board 1000 for signal processing and outputting the AE signal (acoustic wave signal) amplified by the preamplifier as a signal required for diagnosis. .

At this time, the preamplifier 1 actively detects the signal and amplifies the signal. Specifically, the acoustic wave signal detected by the AE sensor is a fine acoustic signal, and the signal strength is Since it is extremely weak, it is generally amplified, and the amplified AE signal (acoustic wave signal) is provided to the DAQ board 1000 according to the present invention.

Hereinafter, a DAQ board for an AET system having a power consumption reduction function according to the present invention will be described in detail with reference to the drawings.

2 is a block diagram of a DAQ board for an AET system having a power consumption reduction function according to the first embodiment of the present invention.

As shown in Figure 2, the DAQ board for the AET system having the power consumption reduction function is largely, a signal input terminal 100, a gain adjustment module 200, a filter module 300, a buffer driver module 400, It includes an A/D converter module 500 , a DSP module 600 , and a mode control module 700 .

More specifically, the signal input terminal 100 receives an acoustic wave signal that is an AE (Acoustic Emission) signal from the external sensor amplifier 1 .

At this time, the signal input terminal 100 may be configured in plurality. When the signal input terminal 100 is configured in plurality, the gain adjustment module 200 , the filter module 300 , and the buffer driver module 400 . , A/D converter module 500 , and mode control module 700 are configured in the same number as the number of signal input terminals 100 to form a matching pair with the signal input terminal 100 . At this time, the DSP module 600 is composed of only one regardless of the number of signal input terminals 100 .

For example, when 8 AE sensors are connected to the DAQ board, 8 signal input terminals 100 are required, and the same number of 8 gain control modules 200, filter module 300, and buffer driver is required. The module 400 , the A/D converter module 500 , and the mode control module 700 are configured to form a matching pair with the signal input terminal 100 .

The gain adjustment module 200 performs a function of amplifying or attenuating an acoustic wave signal that is an AE signal input through the signal input terminal 100 .

For example, if the acoustic wave signal, which is the AE signal, does not have a signal strength of a significant degree for analysis, it is amplified at a preset amplification rate, and if it is a signal having a size enough to cause distortion during amplification, it is attenuated by the preset amplification rate.

The filter module 300 performs a function of removing an unnecessary frequency band noise component included in the amplified or attenuated acoustic wave signal.

For example, if it is composed of a high-pass filter and a high-pass filter and you want to detect only acoustic waves in the 150 to 300 Hz band, use a high-pass filter to The noise component in the frequency band is removed, and the noise component in the frequency band above 300Hz is removed through a high-pass filter.

The buffer driver module 400 performs a function of providing the acoustic wave signal from which the noise component is removed by the filter module 300 to the A/D converter module.

For example, by transforming the A/D converter module 500 into an appropriate size and shape for input, an acoustic wave signal conditioning function is performed.

The A/D converter module 500 converts an acoustic wave signal that is an analog signal provided by the buffer driver module 400 into a digital signal.

The DSP module 600 provides the acoustic wave signal converted into a digital signal to the external analysis device 2 .

The characteristics of the filter module 300 , the buffer driver module 400 , the A/D converter module 500 , and the DSP module 600 are generally widely known in the field of acoustic wave signal processing technology, so only the above description is sufficient. It is obvious that those skilled in the art can fully understand the function.

On the other hand, the mode control module 700, which is a key component of the present invention, controls the DAQ board to operate in the sleep mode or the operation mode using the acoustic wave signal input through the signal input terminal 100, thereby allowing the DAQ in the standby state. By reducing the power consumption of the board, it performs the function of reducing the amount of heat generated by the DAQ board.

For example, in an environment where an acoustic wave signal, which is an intermittent acoustic emission (AE) signal, exists, in the absence of an acoustic wave signal or an acoustic wave signal that has no meaning for signal analysis (too weak or mostly noise signals), By switching the DAQ board to sleep mode to remove standby power in unnecessary situations, it is possible to reduce the amount of heat generated by the DAQ board by reducing power consumption.

That is, the mode control module 700 provides operation power to the DAQ board immediately (with minimum delay) when a significant acoustic wave signal is input from the outside in the sleep mode state of the DAQ board to operate in the operation mode, and a meaningless acoustic wave signal from the outside If it is input (too weak or almost mostly noise signals), it does not provide operating power to the DAQ board, so it switches to sleep mode.

Hereinafter, the function and operation process of the mode control module 700 will be described in detail with reference to the drawings.

As shown in FIG. 2 , the mode control module 700 according to the first embodiment includes a DC removal unit 710 , a trigger unit 720 , a switch control unit 740 , and a power control switch 750 . will be composed

Specifically, the mode control module 700,

a DC removing unit 710 that removes a DC component included in the input acoustic wave signal and provides it to the trigger unit 720 to remove primary noise included in the acoustic wave signal input through the signal input terminal 100;

It is determined whether the lowest value of the acoustic wave signal from which the DC component is removed and the primary noise has been removed is equal to or greater than a threshold value, and if the lowest value is equal to or greater than the threshold value, the first signal is provided to the switch control unit 740 , and if the lowest value is less than the threshold value, the switch control unit 740 ) and a trigger unit 720 for providing a second signal,

When the first signal is provided from the trigger unit 720, an 'ON' control signal is provided to the power control switch 750, and when the second signal is provided from the trigger unit 720, the power control switch 750 is 'OFF' a switch control unit 740 that provides a control signal; and

When an 'ON' control signal is provided, it is switched to 'ON', so that the power supply that causes the DAQ board to operate in operation mode is provided. It is characterized in that it includes a power control switch 750 to make the power supply to operate.

The DC removing unit 710 performs a function of removing a DC component included in the acoustic wave signal input through the signal input terminal 100 and providing it to the trigger unit 720 .

The DC removal unit 710 is configured to include a capacitor to remove a DC component (primary noise) included in the acoustic wave signal input through the signal input terminal, and then provides it to the trigger unit 720 connected to the rear end.

The trigger unit 720 determines whether the minimum value of the acoustic wave signal from which the DC component is removed and the primary noise is removed is equal to or greater than a threshold value, and if the minimum value is equal to or greater than the threshold value, the trigger unit 720 provides the first signal to the switch control unit 740 and the minimum value is greater than or equal to the threshold value. If it is less than the threshold, a function of providing the second signal to the switch control unit 740 is performed.

For example, it is determined whether the lowest value of the acoustic wave signal is equal to or greater than a threshold of 20 dB, and when the value is greater than or equal to 20 dB, the first signal is provided to the switch control unit 740 , while when the minimum value of the acoustic wave signal is lower than the threshold of 20 dB, the switch A second signal is provided to the control unit 740 .

That is, even though the primary noise is removed by removing the DC component, if the lowest value is less than 20dB, the corresponding acoustic wave signal is mostly a noise signal, meaning that the analysis has no meaning. A second signal is provided to 740 .

In addition, if the lowest value of the acoustic wave signal from which the primary noise has been removed by removing the DC component is above the threshold (eg, 20 dB), it means that the corresponding acoustic wave signal is a signal meaningful for analysis. The first signal is provided to the switch control unit 740 for this purpose.

That is, the first signal is a command signal for generating an 'ON' control signal for the switch, and the second signal is a command signal for generating an 'OFF' control signal for the switch.

The switch control unit 740 provides an 'ON' control signal to the power control switch 750 when a first signal is provided from the trigger unit 720 , and when a second signal is provided from the trigger unit 720 , the power control switch In 750, a function of providing an 'OFF control signal is performed.

For example, when a first signal that is a command signal for generating an 'ON' control signal for the switch is obtained, an 'ON' control signal is generated and an 'ON' control signal is provided to the power control switch 750 . .

On the other hand, when a second signal, which is a command signal for generating an 'OFF' control signal for the switch, is obtained, an 'OFF' control signal is generated and an 'OFF' control signal is provided to the power control switch 750 .

The power control switch 750 is switched to 'ON' when an 'ON' control signal is provided from the switch control unit 740, so that the power supply to operate the DAQ board in the operation mode is made, and the 'OFF' control signal is When provided, it is switched 'OFF', resulting in a power supply that puts the DAQ board into sleep mode.

That is, when 'ON' is switched, the main power source (DC POWER) is supplied so that the DAQ board operates in operation mode, and when 'OFF' is switched, the main power source (DC POWER) is supplied to operate the DAQ board in sleep mode. ) is not supplied with power.

In particular, when the 'ON' switching of the power control switch 750 or 'OFF' switching, the target to which the power of the main power source (DC POWER) is supplied or cut off is the gain control module 200 and the filter module 300 . , characterized in that the buffer driver module (400).

The reason for limiting the target to which power of the main power source (DC POWER) is supplied or cut to the gain control module 200, the filter module 300, and the buffer driver module 400 is that the gain control module 200, the filter module ( 300) and the buffer driver module 400 use the most power during operation and have the greatest possibility of malfunction during operation by power supply.

Meanwhile, as shown in FIG. 3 , the mode control module 700 according to the second embodiment includes a DC removal unit 710 , a trigger unit 720 , a timer unit 730 , a switch control unit 740 , and a power supply. It will be configured to include a control switch (750).

Specifically, the mode control module 700,

a DC removing unit 710 that removes a DC component included in the acoustic wave signal input through the signal input terminal 100 and provides it to the signal amplifying unit 720;

It is determined whether the lowest value of the acoustic wave signal from which the DC component is removed and the primary noise is removed is greater than or equal to a threshold (limited to 20 dB as a dependent term), and if the minimum value is greater than or equal to the threshold, a trigger signal is provided to the timer unit 740; If the minimum value is less than the threshold, the trigger unit 720 that does not provide a trigger signal to the timer unit 740 and,

Using whether the trigger unit 720 provides a trigger signal and whether the time count ends, the switch control unit transmits a first signal for enabling the DAQ board to operate in the operation mode or a second signal for enabling the DAQ board to operate in a sleep mode. A timer unit 730 provided as a 740, and

When the first signal is provided from the timer unit 730 , an 'ON' control signal is provided to the power control switch 750 , and when the second signal is provided from the timer unit 730 , the power control switch 750 is 'OFF' a switch control unit 740 that provides a control signal; and

When the 'ON' control signal is provided, it is switched to 'ON', so that the power supply that causes the DAQ board to operate in operation mode is made. It is characterized in that it includes a power control switch 750 to make the power supply to operate.

The difference from the above-described first embodiment is that the timer unit 730 is additionally configured to improve the disadvantages of the first embodiment, which has a weak point in continuity of signal processing.

As shown in FIG. 4 , even in one normal acoustic wave signal, there may be a section in which the lowest value is temporarily lower than or equal to a threshold value (eg, 20 dB) in some cases.

In this case, the first embodiment operates in the sleep mode in a time interval in which the minimum value is less than or equal to a threshold value (eg, 20 dB), and operates in the operation mode in a time interval above the threshold value. Therefore, even though it is a normal acoustic wave signal, if the lowest value temporarily and momentarily falls below the threshold value, it unconditionally switches to the sleep mode, which interferes with the continuity of signal processing by the DAQ board.

In addition, in the first embodiment, the first signal or the second signal is provided to the switch control unit 740 by interlocking with the lowest value of the acoustic wave. As the on and off operation is repeated, the risk of damage increases, and the power supply by the switch that is turned on and off very frequently occurs very frequently, so the sleep mode and the operation mode are crossed very frequently. and there is a risk of being damaged.

For example, as shown in FIG. 4 , when a single normal acoustic wave signal is input to the DAQ board, the DAQ board enters the operation mode in sections S to A and the sleep mode in sections A to B when the minimum acoustic wave is greater than or equal to the threshold. , B to C again operating mode, C to D again to sleep mode, D to E again to operation mode, and E to F again to sleep mode, The signal processing continuity of the DAQ board is not maintained and the possibility of deterioration of the DAQ board increases.

In order to solve this problem (the problem of operating in the sleep mode when the minimum value of the normal acoustic wave signal is temporarily and momentarily less than the threshold value), the timer unit 730 is additionally configured in the second embodiment.

Among the configurations of the second embodiment, the operation characteristics of the trigger unit 720 and the timer unit 730 are different from those of the first embodiment, and the rest of the configuration is the same, so the detailed description of the same configuration as in the first embodiment is omitted, and a characteristic configuration Only the operating characteristics of the in trigger unit 720 and the timer unit 730 will be described.

Specifically, the trigger unit 720 of the second embodiment operates differently from the trigger unit 720 of the first embodiment. That is, the trigger unit 720 of the second embodiment determines whether the lowest value of the acoustic wave signal from which the DC component is removed and the primary noise is removed is equal to or greater than a threshold value, and if the minimum value is equal to or greater than the threshold value, the trigger signal is provided to the timer unit 740 . And, if the minimum value is less than the threshold value, it is characterized in that the operation is performed not to provide a trigger signal to the timer unit 740 .

The trigger signal is a command signal provided to the timer unit to instruct the timer unit 740 to count the time. A trigger signal is provided, and if the lowest value of the acoustic wave signal is less than a threshold (eg, 20dB), a trigger signal is not provided.

The timer unit 730 uses a first signal for allowing the DAQ board to operate in the operation mode or whether the DAQ board can operate in a sleep mode by using whether the trigger signal is provided by the trigger unit 720 and whether the time count ends. A function of providing the second signal to the switch control unit 740 is performed.

Specifically, the timer unit 730 counts time for a preset time, but when a trigger signal is provided in a state in which the time count is finished, the timer unit 730 starts counting the time and sends a first signal to the switch control unit 740 at the same time. ) is provided.

That is, as shown in FIG. 4 , when a trigger signal is provided from the trigger unit 720 at the first S time point when the lowest value of the acoustic wave signal becomes greater than or equal to the threshold value, the time count starts and the first signal is transmitted to the switch control unit 740 at the same time. to enable the DAQ board to operate in operation mode.

Also, when a trigger signal is provided during time counting, the timer unit 730 resets the counted time and starts counting the time again.

Referring to FIG. 4 , the timer unit 730 counting time using the time S as a count start point receives a trigger signal from the trigger unit 720 in the Y section of FIG. 4 , and in the N section of FIG. 4 , the tree The trigger signal is not provided from the rejection 720 .

At this time, when the timer unit 730 during time counting receives a trigger signal from the trigger unit 720, it resets the counted time and repeats the process of starting time counting again, thereby processing a signal for one normal acoustic wave signal. As shown in FIG. 4, the timer unit extends and continues the time counting operation so that the DAQ board continues to count, and the operation mode of the DAQ board is maintained while the timer unit is counting the time. The continuity of signal processing is maintained.

However, in the case of Example 1, the DAQ board is in the operation mode in the section S to A of FIG. 4, to the sleep mode in the section A to B, to the operation mode again in the section B to C, and back to the sleep mode in the section C to D , it operates again in the operation mode in sections D to E and again in sleep mode in sections E to F, so that the signal processing continuity of the DAQ board for one acoustic wave signal is not maintained.

In addition, the timer unit 730 provides a second signal to the switch control unit 740 when a trigger signal is not provided in a state in which the time count is completed.

For example, as shown in FIG. 5 , when an intermittent acoustic wave signal is input to the DAQ board, for signal processing continuity of the first acoustic wave signal, the timer unit extends the time count whenever a trigger signal is provided as described above. However, when the trigger signal is no longer provided, the last time count is performed, and when the trigger signal is not provided when the last time count is finished, the second signal is provided to the switch control unit 740 so that the DAQ board operates in sleep mode. do.

Subsequently, when the second acoustic wave signal is input, the timer unit starts counting time again and simultaneously provides the first signal to the switch control unit 740 so that the DAQ board operates in the operation mode.

In the above, preferred embodiments of the present invention have been illustrated and described, but the present invention is not limited to the specific embodiments described above, and it is common in the technical field to which the present invention pertains without departing from the gist of the present invention as claimed in the claims. Various modifications may be made by those having the knowledge of, of course, and these modifications should not be individually understood from the technical spirit or perspective of the present invention.

100: signal input terminal
200: gain control module
300: filter module
400: buffer driver module
500: A/D converter module
600: DSP module
700: mode control module
1000 : DAQ board

Claims (7)

In the DAQ board for AET system having a power consumption reduction function,

a signal input terminal 100 to which an acoustic wave signal that is an AE (Acoustic Emission) signal is input from the external sensor amplifier 1;
a gain adjustment module 200 for amplifying or attenuating the acoustic wave signal input through the signal input terminal 100;
a filter module 300 for removing unnecessary frequency band noise components included in the amplified or attenuated acoustic wave signal;
a buffer driver module 400 that provides the acoustic wave signal from which the noise component has been removed to the A/D converter module;
an A/D converter module 500 for converting an acoustic wave signal that is an analog signal provided by the buffer driver module 400 into a digital signal;
a DSP module 600 for providing an acoustic wave signal converted into a digital signal to an external analysis device 2;
A mode control module that uses the acoustic wave signal input through the signal input terminal 100 to operate the DAQ board in the sleep mode or operation mode, thereby reducing the power consumption of the DAQ board in the standby state to reduce the amount of heat generated by the DAQ board. (700); including,

The mode control module 700,
a DC removing unit 710 that removes a DC component included in the input acoustic wave signal and provides it to the trigger unit 720 to remove primary noise included in the acoustic wave signal input through the signal input terminal 100;
It is determined whether the lowest value of the acoustic wave signal from which the DC component is removed and the primary noise has been removed is equal to or greater than a threshold value, and if the lowest value is equal to or greater than the threshold value, the first signal is provided to the switch control unit 740 , and if the lowest value is less than the threshold value, the switch control unit 740 ) and a trigger unit 720 for providing a second signal,
When the first signal is provided from the trigger unit 720, an 'ON' control signal is provided to the power control switch 750, and when the second signal is provided from the trigger unit 720, the power control switch 750 is 'OFF' a switch control unit 740 that provides a control signal; and
When an 'ON' control signal is provided, it is switched to 'ON', so that the power supply that causes the DAQ board to operate in operation mode is provided. A DAQ board for AET system with a power consumption saving function, characterized in that it includes a power control switch 750 to enable the power supply to operate.
delete In the DAQ board for AET system having a power consumption reduction function,

a signal input terminal 100 to which an acoustic wave signal that is an AE (Acoustic Emission) signal is input from the external sensor amplifier 1;
a gain adjustment module 200 for amplifying or attenuating the acoustic wave signal input through the signal input terminal 100;
a filter module 300 for removing unnecessary frequency band noise components included in the amplified or attenuated acoustic wave signal;
a buffer driver module 400 that provides the acoustic wave signal from which the noise component has been removed to the A/D converter module;
an A/D converter module 500 for converting an acoustic wave signal that is an analog signal provided by the buffer driver module 400 into a digital signal;
a DSP module 600 for providing an acoustic wave signal converted into a digital signal to an external analysis device 2;
A mode control module that uses the acoustic wave signal input through the signal input terminal 100 to operate the DAQ board in the sleep mode or operation mode, thereby reducing the power consumption of the DAQ board in the standby state to reduce the amount of heat generated by the DAQ board. (700); including,
The mode control module 700,
a DC removing unit 710 that removes a DC component included in the input acoustic wave signal and provides it to the trigger unit 720 to remove primary noise included in the acoustic wave signal input through the signal input terminal 100;
It is determined whether the lowest value of the acoustic wave signal from which the DC component is removed and the primary noise has been removed is equal to or greater than a threshold value, and if the lowest value is equal to or greater than the threshold value, a trigger signal is provided to the timer unit 740, and if the lowest value is less than the threshold value, the timer unit 740 and a trigger unit 720 that does not provide a trigger signal to
Using whether the trigger unit 720 provides a trigger signal and whether the time count ends, the switch control unit transmits a first signal for enabling the DAQ board to operate in the operation mode or a second signal for enabling the DAQ board to operate in a sleep mode. A timer unit 730 provided as a 740, and
When the first signal is provided from the timer unit 730 , an 'ON' control signal is provided to the power control switch 750 , and when the second signal is provided from the timer unit 730 , the power control switch 750 is 'OFF' a switch control unit 740 that provides a control signal; and
When an 'ON' control signal is provided, it is switched to 'ON', so that the power supply that causes the DAQ board to operate in operation mode is provided. A DAQ board for AET system with a power consumption saving function, characterized in that it includes a power control switch 750 to enable the power supply to operate.
4. The method of claim 3,
The timer unit 730,
For a preset time, count the time,
When the trigger signal is provided in the state where the time count is finished, the first signal is provided to the switch control unit 740 at the same time as the time count is started,
If a trigger signal is provided during time counting, the counted time is reset to start time counting again,
When the trigger signal is not provided in the state where the time count is finished, the DAQ board for the AET system having a power consumption saving function, characterized in that it provides the second signal to the switch control unit 740 .
4. The method of claim 1 or 3,
When the power control switch 750 is switched 'OFF' so that the DAQ board operates in the sleep mode, the power supply to the gain control module 200, the filter module 300, and the buffer driver module 400 is cut off. DAQ board for AET system with power consumption reduction function.
4. The method of claim 1 or 3,
The signal input terminal 100 may be composed of a plurality,
When the signal input terminal 100 is configured in plurality, the gain control module 200 , the filter module 300 , the buffer driver module 400 , the A/D converter module 500 , and the mode control module 700 receive the signal A DAQ board for AET system having a power consumption saving function, characterized in that it is composed of the same number as the number of input terminals (100) and forms a matching pair with the signal input terminal (100).
4. The method of claim 1 or 3,
The threshold is
DAQ board for AET system with power consumption saving function, characterized in that it is 20dB.

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