KR102236074B1 - Leak Detection System With External Noise Removal Function - Google Patents

Abstract

The present invention is a leak detection system that outputs an appropriate voltage by avoiding external noise of the leak. According to the present invention, the leak detection system comprises: an arithmetic unit including an input module, an arithmetic module, a noise detection module, a noise comparison module, a reference waveform module, and an output module; a sensor cable unit which includes a first cable sensor module exhibiting different resistances according to the length and having one end connected to a first input line and the other end connected to a second input line, and a second cable sensor module exhibiting different resistances according to the length, spaced apart from the first cable sensor module while being in parallel therewith, and having the other end connected to an output line; and a resistance unit including a first resistor having one end connected to the first input line and the other end that is grounded, and a second resistor having the same resistance value as the first resistor, one end connected to the second input line, and the other end that is grounded.

Description

Leak Detection System With External Noise Removal Function, which outputs an appropriate voltage by avoiding external noise from leakage.

The present invention is a technology related to a system that detects a leak and outputs an appropriate voltage by avoiding external noise of the leak.

Leakage may occur in piping and locations of machinery. For example, leakage may occur in semiconductor facilities or major electronic facilities. Leakage can cause fires and explosions and problems that impair worker safety.

This problem can lead to a situation in which the entire process of a semiconductor facility or electronic facility is paralyzed.

Accordingly, a control system is installed in major industrial facilities to prevent large-scale accidents of fluid leakage. Among many control systems, a system that guarantees accuracy, stability and speed is dominated, and research and development are being conducted on a system that improves these characteristics. For example, as disclosed in Korean Patent Registration No. 10-1216386, a device such as a flat-type leak detection device and a system based on such a detection device are actively researched and developed.

However, in the current sensing device, if the place where the leak detection line is installed is the place where the electric leakage occurs or the electric external noise is severe, the measured value is inaccurate when the leak occurs, so that it is not possible to determine the exact location of the leak. In addition, there is a problem in that the voltage generated by the leakage is not used in the electric device.

Korean Patent Registration No. 10-1216386 (2012.12.21)

In order to solve the above-described problem, the present invention is to provide a system that transmits a signal of a specific frequency to a leak detection line and outputs a specific frequency to avoid external noise based on a specific frequency at the receiving place.

The problem to be solved of the present invention is not limited to the problems mentioned above, and other technical problems that are not mentioned will be clearly understood by those skilled in the art from the following description.

A leakage detection system for outputting an appropriate voltage by avoiding external noise of leakage of the present invention for achieving the above object,

An input module including a first input line connected to the first input terminal and a second input line connected to the second input terminal,

A calculation module for outputting an added voltage by adding the first voltage applied through the first input line and the second voltage applied through the second input line,

A noise detection module for detecting noise included in the first voltage and noise included in the second voltage,

The reference voltage and the reference noise are already set, and after receiving the added voltage and noise from the noise detection module from the calculation module and the noise detection module, connected to the calculation module and the noise detection module, the received addition voltage and the reference voltage, and the received received noise and reference noise In case,

If the added voltage is less than the reference voltage and the reception noise is less than the reference noise, the first detection signal is output.

A noise contrast module that outputs a second detection signal when the added voltage is greater than the reference voltage and the reception noise is greater than the reference noise,

A plurality of detection reference waveforms are preset, and when the first detection signal is received from the noise contrast module, the output detection reference waveform is output.

A reference waveform module that outputs a detection reference waveform different from the output detection reference waveform when the second detection signal is received,

An operation unit connected to the reference waveform module and including an output module including an output terminal configured to output a first detection reference waveform or a second detection reference waveform and an output line connected to the output terminal;

It exhibits different resistances depending on the length,

A first cable sensor module having one end connected to the first input line and the other end connected to the second input line,

A sensor cable unit including a second cable sensor module that exhibits different resistances according to lengths and is spaced apart in parallel with the first cable sensor module and the other end is connected to the output line;

Including a resistance part including a first resistance connected to the first input line, the other end having the same resistance value as the first resistance and the first resistance connected to the second input line, and a second resistance connected to the second input line and the other end connected to the ground do.

The reference waveform module,

It may include a first detection reference waveform that is a sine wave, a second detection reference waveform that is a square wave, a third detection reference waveform that is a triangular wave, and a fourth detection reference waveform that is a sawtooth wave.

The operation unit,

A first amplification module in which the first amplification input terminal is connected to the other end of the second cable sensor module and the first amplification output terminal is connected to the first input terminal,

A second amplification module in which the second amplification input terminal is connected to one end of the second cable sensor module and the second amplification output terminal is connected to the second input terminal,

A third amplification module in which the third amplification input terminal is connected to the output line and the third amplified output terminal is connected to the second cable sensor module may be further included.

The operation unit,

The voltage applied to the first input terminal and the voltage applied to the second input terminal are calculated to detect the leakage resistance unit located in the first cable sensor module and the second cable sensor module.

According to the present invention, when the appropriate voltage is changed due to the noise caused by the leakage liquid affecting the appropriate voltage, the waveform having a small voltage fluctuation width is changed by the leakage and applied to the electric device. Through this, the present invention prevents the electric device from being burned by an inappropriate voltage.

In addition, the present invention allows the administrator to take action by identifying the location of the leak through the sensor cable.

1 is a block diagram of a leakage detection system for outputting an appropriate voltage by avoiding external noise of leakage according to an embodiment of the present invention.
2 is a diagram illustrating an operating state of the operation unit of FIG. 1.
3 is a circuit diagram showing a connection state between an operation unit, a sensor cable unit, and a resistance unit of a leakage detection system that outputs an appropriate voltage by avoiding external noise of leakage according to an embodiment of the present invention.
4 is a view showing a state in which the leakage resistance part is formed in different positions in the sensor cable part of FIG.
5 is a view showing a state in which the leakage resistance part is formed in FIG. 4.
6 is a diagram showing voltages applied to the first resistance and the second resistance by the leakage resistance unit of FIG. 4.
7 to 9 are views showing an operating state of a leak detection system that outputs an appropriate voltage by avoiding external noise of the leak.
10 is a table showing voltages formed in the first resistor and the second resistor when the leakage resistance part is formed at different positions in the first sensor cable module and the second sensor cable module.

Advantages and features of the present invention, and constituent elements for achieving them will become apparent with reference to the embodiments described later in detail together with the accompanying drawings.

However, the present invention is not limited to the embodiments disclosed below and may be implemented in various different forms. The embodiments described in the present invention are merely provided to complete the disclosure of the present invention and to fully inform a person of ordinary skill in the art to which the present invention belongs. In addition, the operation unit disclosed in the present invention may be formed as a computer capable of calculating various types of data by installing a program.

In the present specification, first, the present invention will be generally described with reference to FIGS. 1 to 5 so that the description of the present invention may be concise and clear.

FIG. 1 is a block diagram of a leak detection system that outputs an appropriate voltage by avoiding external noise of a leak according to an embodiment of the present invention, and FIG. 2 is a diagram illustrating an operation state of an operation unit of FIG. 1. And FIG. 3 is a circuit diagram showing a connection state between the operation unit, the sensor cable unit, and the resistance unit of the leakage detection system outputting an appropriate voltage by avoiding external noise of leakage according to an embodiment of the present invention. It is a diagram showing a state in which the leakage resistance part is formed in different positions on the sensor cable part.

In the leakage detection system (1, hereinafter, leakage detection system) that outputs an appropriate voltage by avoiding the external noise of leakage, the noise caused by the leakage affects the appropriate voltage, so when the appropriate voltage is changed, the voltage fluctuation width is increased by the leakage. The small waveform is changed and output. Then, the output voltage waveform is applied to the electric equipment so that the electric equipment is not damaged by an inappropriate voltage. In addition, the leakage detection system 1 can quickly and accurately detect whether or not a leakage has occurred while showing a rapid change in voltage at both ends and even a minute change. Through this, the leakage detection system 1 allows the administrator to determine the location of the leakage so that the administrator can take action on the leakage.

The leakage detection system 1 having such a characteristic includes an operation unit 10, a sensor cable unit 20, and a resistance unit 30 as constituent elements.

Hereinafter, features and components of the operation unit 10, the sensor cable unit 20, and the resistance unit 30 will be described in detail.

After analyzing the noise caused by the leakage in the input voltage, the calculating unit 10 may output a voltage suitable for the electric device. The length of the sensor cable unit 20 is set in the calculation unit 10, and a detection reference waveform for a size of 0 to 24V may be periodically and repeatedly output. For example, the operation unit 10 may output a source signal, that is, a detection reference waveform, as shown in FIG. 2A. In addition, as shown in (b) of FIG. 2, the voltage applied to the first resistor 310 and the voltage applied to the second resistor 320 as shown in (c) of FIG. 2 may be added. In this case, when the sum of the added voltages is 2V as an example of the reference voltage, as shown in FIG. 2D, generation of the detection reference waveform may be stopped.

In addition, when the sum applied through the resistor unit 30 is 2V, the value formed in the first resistor 310 is 1V, and the value formed in the second resistor 320 is 1V, the operation unit 10 is It can be seen that it occurred at the midpoint. This operation unit 10 may be a computer.

Such an operation unit 10 includes an input module 110, an operation module 120, a noise detection module 130, a noise contrast module 140, a reference waveform module 150, an output module 160, and a first amplification module. 171, a second amplification module 172 and a third amplification module 173 as components. Here, the input module 110 includes a first input terminal 111 and a second input terminal 112 and a first input line 1111 connected to the first input terminal 111 and a second input line connected to the second input terminal 112. Including (1121). At this time, the first input line 1111 is connected to the first resistor 310 to be described later so that the voltage applied to the first resistor 310 is applied to the first input terminal 111, and the second input line 1111 Is connected to the second resistor 320 to be described later, so that the voltage applied to the second resistor 320 is applied to the second input terminal 112.

The calculation module 120 becomes a module that outputs an added voltage. The calculation module 120 outputs an added voltage by adding the first voltage applied through the first input line 1111 and the second voltage applied through the second input line 1121. For example, the calculation module 120 may linearly add the magnitude of the first voltage and the magnitude of the second voltage and output the added voltage. More specifically, the calculation module 120 may output a sine wave having a size of 4V by adding a first voltage that is a sine wave having a size of 2V and a sine wave having a size of 2V.

The noise detection module 130 extracts noise by receiving voltage data from the calculation module 120. For example, the noise detection module 130 may detect a first noise included in the first voltage and a second noise included in the second voltage.

The noise contrast module 140 compares the added voltage and the reference voltage, the received received noise and the reference noise, and outputs a first detection signal or a second detection signal according to a contrast value.

More specifically, the noise contrast module 140 has a reference voltage and a reference noise set in advance, and is connected to the calculation module 120 and the noise detection module 130, and the added voltage and the noise detection module 130 from the calculation module 120 ) To receive noise. Thereafter, the received added voltage and reference voltage, and the received received noise and reference noise are compared. At this time, when the added voltage is less than the reference voltage and the reception noise is less than the reference noise, the first detection signal is output, and when the added voltage is greater than the reference voltage and the reception noise is greater than the reference noise, the second detection signal is output.

The reference waveform module 150 may output various detection reference waveforms according to a detection signal received from the noise contrast module 140. The reference waveform module 150 includes a first detection reference waveform (SW1), a second detection reference waveform (SW2), a third detection reference waveform (SW3), and a fourth detection reference waveform (SW4) shown in FIG. May be set.

The reference waveform module 150 outputs a detection reference waveform that was output upon receiving the first detection signal from the noise contrast module 140, and outputs a detection reference waveform different from the output detection reference waveform when receiving the second detection signal. . For example, the reference waveform module 150 outputs the first detection reference waveform SW1, and when the first detection signal is received, outputs the first detection reference waveform SW1, and the first detection reference waveform SW1 is During output, when a second detection signal is received, a second detection reference waveform SW2 is output.

In addition, the reference waveform module 150 outputs the second detection reference waveform SW2, then outputs the second detection reference waveform SW2 when the first detection signal is received, and a third detection when the second detection signal is received again. The reference waveform (SW3) is output. And the reference waveform module 150 outputs the third detection reference waveform (SW3), and when the first detection signal is received, outputs the third detection reference waveform (SW3), and when the second detection signal is received, the fourth detection reference The waveform SW4 is output. Here, the first detection reference waveform SW1 becomes a sine wave, and the second detection reference waveform SW2 becomes a square wave. In addition, the third detection reference waveform SW3 may be a sawtooth wave, and the fourth detection reference waveform SW4 may be a triangular wave.

The output module 160 outputs detection reference waveforms SW1 to SW4 output from the reference waveform module 150. For example, the output module 160 includes a first detection reference waveform (SW1), a second detection reference waveform (SW2), a third detection reference waveform (SW3) and a fourth detection reference waveform output from the reference waveform module 150. (SW4) is output. The output module 160 includes an output terminal 161 and an output line 1611 connected to the output terminal 161. The first amplification module 171, the second amplification module 172, and the third amplification module 173 may be formed as operational amplifiers. The non-inverting terminal of the operational amplifier is connected to the operation unit 10, and the inverting terminal is connected to the output terminal, so that the voltage output from the output terminal is equal to the voltage applied to the non-inverting terminal. That is, since the augmentation module is formed in a negative feedback structure, it is possible to lower the final voltage gain to increase operational stability and make the output voltage equal to the input voltage.

Here, in the first amplification module 171, the first amplification input terminal is connected to the other end of the second cable sensor module, and the first amplification output terminal is connected to the first input terminal 111. In addition, in the second amplification module 172, the second amplification input terminal is connected to one end of the second cable sensor module, and the second amplification output terminal is connected to the second input terminal 112. In addition, in the third amplification module 173, a third amplification input terminal may be connected to the output line 1611, and a third amplification output terminal may be connected to the second cable sensor module 220.

In addition, the calculation unit 10 calculates the voltage applied to the first input terminal 111 and the voltage applied to the second input terminal 112 through the sensor cable unit 20 to provide the first cable sensor module 210 and the second The leakage resistance part 40 located between the cable sensor modules 220 may be detected. Here, the leakage resistance unit 40 may be a resistance generated by a leaked liquid.

The sensor cable unit 20 allows current to be conducted according to the occurrence of leakage and detects the occurrence of leakage. The sensor cable part 20 is connected to the first cable sensor module 210 and the second input line 1121 connected to the first input line 110, and is spaced apart in parallel with the first cable sensor module 210. It may include a second cable sensor module 220. Such a sensor cable unit 20 detects leakage located between the first cable sensor module 210 and the second cable sensor module 220, and leakage noise is added to the voltage output from the operation unit 10, so that the operation unit Apply the noisy voltage to (10). In the present specification, the first cable sensor module 210 and the second cable sensor module 220 have a length of 10 m as shown in FIG. 4 so that the description of the sensor cable part 20 may be concise and clear. It becomes a cable sensor with a resistance value of 10Ω per 1m.

The resistor unit 30 includes a first resistor 310 and a second resistor 320. The resistance part 30 may be connected to one end and the other end of the sensor cable part 10. Here, the first resistor 310 has one end connected to one end of the second input line 120, the other end is grounded to the ground, and the second resistor 320 is the other end of the second input line 120 One end may be connected to the ground and the other end may be grounded to the ground. In this specification, the values of the first resistor 310 and the second resistor 320 are 100Ω for convenience of calculation.

The resistance unit 30 forms a voltage by the current flowing through the leakage resistance unit 40 located between the first cable sensor module 210 and the second cable sensor module 220.

The leakage resistance unit 40 becomes a liquid that causes noise to be trapped in the voltage output from the operation unit 10. This leakage resistance unit 40 is formed between the first cable sensor module 210 and the second cable sensor module 220 to open the first cable sensor module 210 and the second cable sensor module 220 ( It can be converted into an open circuit or a closed circuit. As an example, when the leakage resistance unit 40 is formed between the first cable sensor module 210 and the second cable sensor module 220, the first cable sensor module 210 and the second cable sensor module 220 Is formed as a closed circuit, and when not formed between the first cable sensor module 210 and the second cable sensor module 220, it is formed as an open circuit.

Hereinafter, with reference to FIGS. 4 to 10, the operation of the components of the present invention and the corresponding current and voltage values will be described in detail.

5 is a view showing a state in which a leakage resistance part is formed in FIG. 4, FIG. 6 is a view showing voltages applied to the first and second resistances by the leakage resistance part of FIG. 4, and FIGS. 7 to 9 It is a diagram showing the operating state of the leakage detection system that outputs an appropriate voltage by avoiding external noise of And Figure 10 is a table showing the voltage formed in the first resistance and the second resistance when the leakage resistance part is formed at different positions in the first sensor cable module and the second sensor cable module.

In the leakage detection system 1, as shown in FIG. 5, the calculation unit 10 is connected to the sensor cable unit 20 and the resistance unit 40, and the leakage resistance unit 40 is connected to the sensor cable unit 20. As it is positioned, it outputs a voltage that is noisy due to leakage. As an example, when the leakage resistance unit 40 is formed at an intermediate point between the first cable sensor module 210 and the second cable sensor module 220, as shown in FIG. 6, the first A value formed in the resistor 310 may sense 1V, and a value formed in the second resistor 320 may sense 1V.

In addition, the operation unit 10 is the position of the leakage resistance in the first cable sensor module 210 and the second cable sensor module 220 through the voltage applied to the first resistor 310 and the second resistor 320 Can grasp. For example, when the leakage resistance is formed at one end of the first cable sensor module 210 and the second cable sensor module 220, as shown in Figure 7 (a), 1, a voltage of 1.34V formed on the resistor 310 and a voltage of 0.66V formed on the second resistor 320 are applied, so that the leakage resistance unit 40 connects to one end of the first cable sensor module 210 and the second cable sensor module ( 220).

And the operation unit 10, as shown in Figure 7 (b), when the leakage resistance unit 40 is formed at the intermediate point between the first cable sensor module 210 and the second cable sensor module 220, When the voltage formed through the first resistor 310 and the second resistor 320 is applied, the leakage resistance part is 5m away from the other ends of the first cable sensor module 210 and the second cable sensor module. Know your location.

In addition, when the leakage resistance unit 40 is formed in the first cable sensor module 210 and the second cable sensor module 220, the operation unit 10 includes a first detection reference waveform (SW1) to a fourth detection reference waveform. It outputs (SW4), and can output a voltage that is minimally affected by noise by the leakage resistance unit 40.

As an example, when the leakage resistance unit 40 is formed in the first cable sensor module 210 and the second cable sensor module 220, as shown in FIG. 7, the first detection reference waveform (SW1) may be output, and a noise voltage with noise may be applied to the first detection reference waveform SW1. Then, noise is extracted from the applied noise voltage, and compared with the reference noise, it is determined whether the voltage with noise is a voltage that can be applied to the electric device. In this case, the operation unit 10 is the sum of the first voltage formed in the first resistor 310 and the second voltage formed in the second resistor 320 when the noise voltage applied to the first detection reference waveform SW1 is equal to or greater than the reference noise. When the added voltage is greater than the reference voltage, a second detection signal is output. In addition, the second detection reference waveform SW2 may be output as shown in FIG. 8 through the second detection signal. In addition, the calculation unit 10 adds the noise applied to the second detection reference waveform SW2 is smaller than the reference noise and is the sum of the first voltage formed in the first resistor 310 and the second voltage formed in the second resistor 320. When the voltage is less than the reference voltage, the second detection reference waveform SW2 may be output.

On the other hand, as shown in FIG. 9 (a), the operation unit 10 has a noise applied to the second detection reference waveform SW2 greater than the reference noise, and the first voltage and the second resistance formed in the first resistor 310 When the sum of the second voltages formed at 320 is greater than the reference voltage, the third detection reference waveform SW3 may be output as shown in FIG. 9B.

The operation unit 10 receives the voltage output from the first resistor 310 and the second resistor 320 through the second amplification module 172 and the third amplification module 173 to obtain a voltage having noise due to leakage. It can be stably licensed.

In addition, the calculation unit 10 divides the sensor cable unit 20 at regular intervals, and when the leakage resistance unit 40 is located at the partitioned intervals, the voltage formed at one end and the other end of the sensor cable unit 10 is shown in the table. It further includes a voltage table section for output and display. In addition, when the leakage resistance unit 40 is located in the first cable sensor module 210 and the second cable sensor module 220, the voltage table unit inputs a first input from the voltage level formed at the A side voltage and the B side voltage. The values of the line separation resistance and the second input line separation resistance can be calculated. As an example, when the resistance value of the leakage resistance part is 0.0001Ω, the voltage table part, as shown in FIG. 10, the voltage applied to the first resistor, the voltage applied to the second resistor, the current applied to the first resistor, and the first resistor. 2 The current applied to the resistor can be calculated. In addition, the location of the leakage resistance unit may be identified through the ratio of the calculated value between the first resistance and the second resistance.

Although the embodiments of the present invention have been described with reference to the accompanying drawings, those of ordinary skill in the art to which the present invention pertains can be implemented in other specific forms without changing the technical spirit or essential features. You will be able to understand. Therefore, it should be understood that the embodiments described above are illustrative in all respects and not limiting.

1: Leakage detection system that outputs appropriate voltage by avoiding external noise of leakage
10: operation unit
110: input module
111: first input terminal 112: second input terminal
1111: first input line 1121: second input line
120: calculation module
130: noise detection module 140: noise contrast module
150: reference waveform module 160: output module
171: first amplification module 172: second amplification module
173: third amplification module
20: sensor cable part
210: first cable sensor module 220: second cable sensor module
30: resistance part
310: first resistance 320: second resistance
40: leakage resistance part
SW1: first detection reference waveform SW2: second detection reference waveform
SW3: 3rd detection reference waveform SW4: 4th detection reference waveform

Claims (4)

An input module 110 including a first input line 1111 connected to the first input terminal 111 and a second input line 1121 connected to the second input terminal 112,
A calculation module 120 for outputting an added voltage by adding a first voltage applied through the first input line 1111 and a second voltage applied through the second input line 1121, and
A noise detection module 130 for detecting noise included in the first voltage and noise included in the second voltage,
The reference voltage and the noise detection module 130 are pre-set and connected to the calculation module 120 and the noise detection module 130 to receive the added voltage from the calculation module 120 and the noise from the noise detection module 130, and then the received addition. In contrast to the voltage and reference voltage and received received noise and reference noise,
Noise contrast module 140 that outputs a first detection signal when the added voltage is less than the reference voltage and the reception noise is less than the reference noise, and outputs a second detection signal when the added voltage is greater than the reference voltage and the reception noise is greater than the reference noise. and,
A plurality of detection reference waveforms are preset and upon receiving the first detection signal from the noise contrast module 140, the output detection reference waveform is output,
A reference waveform module 150 for outputting a detection reference waveform different from the output detection reference waveform when the second detection signal is received,
An output module having an output terminal 161 connected to the reference waveform module 150 to output a first detection reference waveform (SW1) or a second detection reference waveform (SW2) and an output line 1611 connected to the output terminal 161 An operation unit 10 including 160;
It exhibits different resistances depending on the length,
A first cable sensor module 210 having one end connected to the first input line 1111 and the other end connected to the second input line 1121,
A sensor cable unit 20 including a second cable sensor module 220 having different resistances according to the length and spaced in parallel with the first cable sensor module 210 and connected to the output line 1611 at the other end;
One end is connected to the first input line 1111 and the other end has the same resistance value as the first resistor 310 and the first resistor 310 grounded, and one end is connected to the second input line 1121, and the other end is A leakage detection system for outputting an appropriate voltage by avoiding external noise of the leakage, including a resistance unit 30 including a grounded second resistance 320. The method of claim 1,
The reference waveform module 150,
Outside of leakage, including the first detection reference waveform (SW1) which is a sine wave, the second detection reference waveform (SW2) which is a square wave, the third detection reference waveform (SW3) which is a sawtooth wave, and the fourth detection reference waveform (SW4) which is a triangular wave A leak detection system that avoids noise and outputs an appropriate voltage. The method of claim 1, wherein the calculation unit 10,
A first amplification module 171 in which the first amplification input terminal is connected to the other end of the second cable sensor module and the first amplification output terminal is connected to the first input terminal 111,
A second amplification module 172 in which a second amplification input terminal is connected to one end of the second cable sensor module and a second amplification output terminal is connected to the second input terminal 112,
The third amplification input terminal further comprises a third amplification module 173 connected to the output line 1611 and the third amplified output terminal connected to the second cable sensor module 220, avoiding external noise from leakage and providing an appropriate voltage. Leakage detection system that outputs. The method of claim 1, wherein the calculation unit 10,
By calculating the voltage applied to the first input terminal 111 and the voltage applied to the second input terminal 112, the leakage resistance part 40 located in the first cable sensor module 210 and the second cable sensor module 220 A leak detection system that outputs an appropriate voltage by avoiding the external noise of the leak to be detected.

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