KR20230112408A - Leak detection sensor with a function of diagnosing whether the sensing electrode is disconnected or not - Google Patents

Abstract

본 발명은 한쌍의 센싱전극 단부에 LC직렬 공진회로를 부착하고 그 공진회로에 주기적인 진단신호의 공급을 통해 검출한 임피던스와 전류를 기반으로 산출한 공진특성곡선을 이용하여 센싱전극의 단선여부를 확인할 수 있는 누액감지센서에 관한 것으로, 한쌍의 센싱전극 일단부에 LC직렬 공진회로가 연결되고, 제1전극의 타단부에는 전원공급부 및 억제커패시터의 일단자가 연결되며, 제2전극의 타단부에는 전압검출부 및 제어부가 연결되고, 상기 전원공급부와 억제커패시터(Cs)의 타단자는 제어부에 연결되되, 그 제어부에는 억제커패시터(Cs)에 LC직렬 공진회로의 공진주파수(Fr)를 기준으로 상·하한의 경계주파수(F _H, F _L )의 범위에서 가변되는 주파수의 전원을 공급하고, 상기 LC직렬 공진회로에서 피드백되는 신호를 통해 공진특성곡선을 산출하여 미리 저장된 기준곡선과 비교하여 센싱전극의 단선여부를 진단할 수 있도록 구성한 것을 특징으로 한다. According to the present invention, the structure of a pair of sensing electrodes in the leak detection sensor can be simplified, and the disconnection of the sensing electrodes can be easily diagnosed without having a separate multi-switching unit or power polarity switching unit.

Description

Leak detection sensor with a function of diagnosing whether the sensing electrode is disconnected or not}

The present invention relates to a leak detection sensor having a function for diagnosing whether or not a sensing electrode is disconnected, and more particularly, to a leak detection sensor configured to attach an inductor (L)-capacitor (C) series resonance circuit to one end of a pair of sensing electrodes, and to check whether the sensing electrode is disconnected using a resonance characteristic curve calculated based on a correlation between impedance and current detected through periodic supply of a diagnostic signal to the resonance circuit.

When chemicals leak out from storage tanks or pipes, they can cause fatal accidents to the human body as well as contaminate the natural environment, so special care is required in handling chemicals.

Various types of leak detection sensors are used in such a leak detection system. Representatively, a resistive leak detection sensor using a linear characteristic of a current voltage and a reactive leak detection sensor using a permittivity characteristic are well known. However, since most of the existing leak detection systems are operated on the premise that the sensing electrodes operate normally, the importance of technology that can identify operational errors due to defects in the sensing electrodes has recently been emphasized. In line with this trend, technologies for diagnosing disconnection of the sensing electrodes are continuously being announced.

Patent No. 10-0720741 (Prior Patent 1) includes a means for applying a constant voltage to the terminals of the first and second pair wires comprising the first and second conductor wires and a means for converting the leakage current flowing through each pair wire into a voltage when leakage occurs, and the input/output terminals of the means for applying the constant voltage and the means for converting the leakage current to voltage are selectively alternately connected every predetermined time to determine the location of leakage and whether the pair wire is disconnected. A technology is disclosed.

In addition, Patent No. 10-2086975 (Prior Patent 2) discloses a technology for constantly measuring whether or not a sensor cable is disconnected (fault) by configuring a sensor cable with first and second sensors composed of a power line and a sensing line, respectively, and applying a constant voltage through a standard resistor provided between a variable voltage unit supplying power to the sensor cable and the first and second sensors of the sensor cable to measure a microvoltage generated in the disconnection detection resistor.

However, prior patents 1 and 2 above are structurally complex in that they require 4 conductor wires, and since a separate multi-switching unit or power polarity switching unit must be provided, not only does the manufacturing cost of the leak sensor increase, but also the multi-switching unit or the power polarity switching unit.

(Prior Patent Document 1) Patent No. 10-0720741 (Prior Patent Document 2) Patent No. 10-2086975

An object of the present invention is to provide a leak detection sensor that can easily check whether or not the sensing electrode is disconnected through an L-C series resonance circuit attached between the pair of sensing electrodes without having to configure a pair of sensing electrodes with a single wire instead of a pair wire to simplify the wiring structure and to have a separate multi-switching unit or power polarity switching unit.

In addition, an object of the present invention is to provide a leak detection sensor that can easily check whether or not a wire is disconnected by supplying a frequency that varies up and down around a resonance frequency confirmed through a preliminary simulation to an L-C series resonance circuit attached between a pair of sensing electrodes and using a resonance characteristic curve calculated based on the correlation between the feedback impedance and current.

According to a preferred embodiment of the present invention, the leak detection sensor having a disconnection diagnosis function of the sensing electrodes has an LC _series resonance circuit connected to one end of a pair of sensing electrodes, one end of a power supply unit and a suppression capacitor connected to the other end of the first electrode, and a voltage detection unit and a control unit connected to the other end of the second electrode. It is characterized in that it is configured to diagnose whether the sensing electrode is disconnected by calculating a resonance _{characteristic} curve through a signal fed back from the LC series resonance circuit and comparing it with a pre-stored reference curve.

In addition, the leak detection sensor of the present invention is characterized in that the L-C series resonance circuit is accommodated in a housing equipped with an electromagnetic wave shielding means or molded with an electromagnetic wave shielding material and connected to one end of a pair of sensing electrodes.

In addition, the leak detection sensor of the present invention is characterized in that the control unit further includes a function of driving an alarm or transmitting a diagnosis result of whether a pair of sensing electrodes are disconnected to a control server.

In addition, the leak detection sensor of the present invention is characterized in that the control unit further includes a function to support alternate execution of a leak detection mode and a diagnosis mode for disconnection of the sensing electrode.

In addition, the leak detection sensor of the present invention is characterized in that the alternate execution cycle of the leak detection mode and the diagnostic mode for disconnection of the sensing electrode is variably controlled according to the cumulative use time of the leak detection sensor.

According to the present invention, it is possible to simplify the electrode structure of the leak detection sensor, and there is an effect that the manufacturing cost can be expected to be reduced thereby.

In addition, according to the present invention, since it is possible to calculate the resonance characteristic curve based on the feedback impedance and current by supplying a frequency that varies up and down around the resonance frequency (Fr), there is an effect that can easily diagnose whether or not the sensing electrode is disconnected without having a separate multi-switching unit or power supply polarity switching unit.

1 is an exemplary view for explaining a general leak detection alarm system.
2 is a configuration diagram for explaining a conventional leak detection sensor (Prior Patent 1).
3 is a configuration diagram for explaining a conventional leak detection sensor (Prior Patent 2).
4 is an exemplary diagram for explaining the leak detection sensor of the present invention.
5 is an exemplary view showing the characteristics of the LC series resonant circuit of the present invention.

Hereinafter, a leak detection alarm system according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

For reference, in the description of the present invention, if it is determined that a detailed description of a known configuration or function may unnecessarily obscure the subject matter of the present invention, a detailed description thereof will be omitted. In addition, the technical terms used in the present invention are used only to describe specific embodiments, and are not intended to limit the present invention, and the technical terms used in the present invention should be interpreted in a meaning commonly understood by those of ordinary skill in the art to which the present invention belongs, but should not be interpreted in an excessively comprehensive or excessively reduced meaning unless otherwise defined in the present invention.

1 shows the configuration of a general leak detection alarm system. As illustrated in FIG. 1, a general leak detection sensor is buried or attached around a chemical storage tank or pipe. When power is supplied to a pair of sensing electrodes 11 and 12 and there is no leakage between the sensing electrodes 11 and 12, voltage is not detected because there is no current flowing in the resistance SR of the voltage sensing unit 30. As a result, a current path is formed so that the voltage can be detected at the resistance (SR) of the voltage sensing unit 30, and the detected voltage is analyzed by the control unit 40 to drive the alarm 50 or through the communication network 70. It is configured to transmit to the control room server 80. At this time, the control unit 40 controls the on/off of the transistor Q1 at a predetermined cycle to support checking whether leakage occurs. In the leak alarm system of FIG. 1 , when a leak is detected between a pair of electrodes 11 and 12, the control unit 40 analyzes the detection signal of the voltage sensor 30, and according to the analysis result, the control room server 80 notifies the leak through the communication network 70 or warns the administrators of the leak through the alarm driving unit 50, and is operated so that the administrators can promptly and appropriately deal with the leak situation according to the notification or warning.

However, if the sensing electrodes 11 and 12 of the leak detection sensor do not operate normally, it may not promptly warn of the leak, causing an accident, or an unnecessary alarm caused by a malfunction may relieve administrators' alertness.

Accordingly, various technologies for diagnosing whether the sensing electrodes of the leak detection sensor are operating normally have emerged. FIGS. 2 and 3 show representative prior art previously mentioned as Prior Patents 1 and 2.

First, the leak detection sensor in FIG. 2 shows the structure of a pair of sensing electrodes 100. The sensing electrodes 100 are composed of two pair wires consisting of a first conductor wire 200, 230 having excellent conductivity and a second conductor wire 210, 220 having a resistance component. A technology that can check whether a pair wire is disconnected is disclosed.

And the leak detection sensor of FIG. 3 includes a sensor cable 100 composed of a first sensor 110 connected by a first power line 111 and a first sensing line 112 and a second sensor 120 connected by a second power line 1231 and a second sensing line 122, and a standard resistance 410 installed between the first sensor 110 and the second sensor 120 and a stage that always generates a microvoltage. It is composed of a line sensing resistor 500, and a technique of measuring whether or not a sensor cable is disconnected (Fault) by measuring a microvoltage of the disconnection sensing resistor 500 is shown.

However, the prior art of FIGS. 2 and 3 is composed of a pair of sensing electrodes consisting of a pair wire consisting of a power wire and a sensing line, respectively, so it is difficult to avoid the manufacturing cost of the sensing electrode, and the process of controlling a separate multiswiing unit 120 or the power transformance 600 is required, and the circuit becomes complicated, and the control command to diagnose the normal operation of the sensing electrode There was a structural limit that the data traffic in the microcom (controller) was inevitably increased by processing.

The present invention was created to overcome the limitations of the prior art, and a pair of sensing electrodes are each made in a single-line structure to simplify the sensing circuit, and a simple L-C series resonant circuit is added without requiring a separate switching means for power supply. It proposes a leak detection sensor that can easily diagnose whether or not the sensing electrode is disconnected.

4 is an exemplary view for explaining a leak detection sensor according to a preferred embodiment of the present invention. The leak detection sensor of FIG. 4 includes a pair of sensing electrodes 01 and 02, a power supply unit 06, a voltage detection unit 04, and a control unit 05 as main components. The pair of sensing electrodes 01 and 02 are each made of a single wire, and an L-C series resonance circuit 03 in which an inductor L and a capacitor C are connected in series are coupled to one end of the sensor. At this time, since the leak detection sensor of FIG. 4 is based on a resistive sensor, DC power must be supplied to the first electrode 01 from the power supply unit 06, and the resonance circuit 03 connected to the end of the sensing electrode must be noted that it must be specifically designed as an L-C series resonance circuit.

In addition, the control unit 05 is designed to include a function of supplying a variable frequency in a certain range up and down based on the resonance frequency (Fr) confirmed through a preliminary simulation, a function of detecting a signal fed back from the sensing electrodes 01 and 02 in response to the variable frequency, and a function of calculating a resonance characteristic curve based on impedance and current, and a function of determining whether the sensing electrode is disconnected by comparing the calculated resonance characteristic curve with a pre-stored reference characteristic curve. The judgment result at this time can be transmitted to the control server through a communication network or notified to the manager through an alarm so that countermeasures can be taken.

5, the resonance frequency (Fr) of the LC series resonance circuit can be specified by Equation 1, and a resonance characteristic curve calculated based on the resonance frequency (Fr) is illustrated. At this time, the variable frequency supplied to calculate the resonance characteristic curve from the controller 05 is designed to be variable in the upper and lower boundary frequencies (F _{H ,} F _L ) based on the resonance frequency (Fr) of the LC series resonance circuit 03 confirmed through a preliminary simulation. As long as the upper and lower boundary frequencies (F _{H and} F _L ) here are in the range where the resonance characteristic curve is calculated enough to confirm the normal operation of the sensing electrodes 01 and 02, the boundary frequencies can be arbitrarily set without particular restrictions. It will be possible.

In general, since the L-C series resonant circuit is vulnerable to external noise, it would be preferable to accommodate it in a housing having a separate electromagnetic shielding means or to combine it with the end of the sensing electrode in a state molded with an electromagnetic shielding material. In addition, it is desirable to install a suppression capacitor (Cs) between the power supply unit 06 and the P2 terminal of the control unit in order to prevent the DC power of the power supply unit 06 from flowing back to the control unit 05.

The leak detection sensor of FIG. 4 can be operated by distinguishing between a normal leak detection mode and a diagnosis mode for checking whether or not the sensing electrodes 01 and 02 are disconnected.

First, in the leak detection mode, since the sensing electrodes 01 and 02 are spaced apart at a certain distance and there is a capacitor C coupled to both ends, no voltage signal is normally transmitted to the P3 terminal of the control unit 05. It is transmitted to the control server to notify the fact of leakage. At this time, DC power is supplied to the first electrode 01 through the P1 terminal of the control unit 05, and the suppression capacitor Cs prevents the DC power from flowing back to the P2 terminal of the control unit 05.

Next, in the diagnostic mode of the sensing electrodes 01 and 02, a frequency varying in the range of upper and lower boundary frequencies F _{H and} F _L centered on the resonance frequency Fr of the resonance circuit 03 is periodically supplied through the P2 terminal of the control unit 05, and a signal fed back in response to the frequency is transmitted to the P3 terminal of the control unit 05 to calculate a resonance characteristic curve as shown in FIG. 5. At this time, it would be desirable to design so that the DC power supply (06) is cut off through the P1 terminal of the controller (05). The resonance characteristic curve calculated through this process is compared with the reference characteristic curve stored in advance through preliminary simulation to diagnose whether or not the sensing electrodes (01, 02) are disconnected, and informs the manager of the diagnosis result so that follow-up measures can be taken. Here, the suppression capacitor (Cs) may affect the resonance characteristic curve of the LC series resonance circuit, but the present invention calculates and stores the reference resonance characteristic curve including the suppression capacitor (Cs) through a pre-simulation process, so the suppression capacitor (Cs) will not have a special effect in the diagnosis mode.

On the other hand, it is desirable to run the above two modes alternately. While the risk of malfunction is relatively low at the beginning of the installation of a new sensor, the possibility of malfunction is relatively high due to the aging of the sensor's protective film or pipe coating as the use time accumulates. Therefore, setting the cycle of the diagnosis mode long at the time of new installation and shortening the cycle of the diagnosis mode as the usage time accumulates will contribute to improving the stability and reliability of the leak detection sensor.

According to the present invention, since a pair of sensing electrodes in the leak detection sensor can be manufactured in a single-wire structure, the structure can be simplified, and there is an effect that the manufacturing cost can be expected to be reduced thereby.

In addition, according to the present invention, since it is possible to calculate a resonance characteristic curve based on the correlation between the feedback impedance and the current by supplying a frequency that varies up and down around the resonance frequency (Fr), there is an effect of easily diagnosing whether or not the sensing electrode is disconnected without a separate multi-switching unit or power supply polarity switching unit.

Although the preferred embodiments of the present invention have been described above, the present invention is not limited to the above-described embodiments, and anyone skilled in the art can make various modifications without departing from the gist of the present invention.

01: 1st electrode 02: 2nd electrode 03: LC series resonance circuit
04: voltage detection unit 05: control unit Cs: suppression capacitor

Claims (5)

In the leak detection sensor having a function of diagnosing whether the sensing electrodes (01, 02) included in the resistive leak detection sensor are disconnected,
An LC series resonant circuit 03 is connected to one end of the sensing electrodes 01 and 02, and one end of a power supply 06 and a suppression capacitor Cs is connected to the other end of the first electrode 01, and a voltage detector 04 and a control unit 05 are connected to the other end of the second electrode 02,
The power supply unit 06 and the other terminal of the suppression capacitor Cs are connected to the control unit 05,
The control unit 05 supplies a variable frequency in the range of upper and lower boundary frequencies (F _H, F _L ) based on the resonance frequency (Fr) of the LC series resonance circuit to the suppression capacitor (Cs), and the LC series resonance circuit. Sensing characterized in that it is configured to determine whether or not the sensing electrodes (01, 02) are disconnected by calculating a resonance characteristic curve through a signal fed back from the circuit and comparing it with a pre-stored reference characteristic curve Leak detection sensor equipped with a function to diagnose whether the electrodes (01, 02) are disconnected According to claim 1,
The LC series resonant circuit (03) is accommodated in a housing having an electromagnetic wave shielding means or molded with an electromagnetic wave shielding material and connected to one end of the sensing electrodes (01, 02) Leak detection sensor with a function for diagnosing whether the sensing electrodes (01, 02) are disconnected According to claim 1,
The control unit (05) further includes a function of driving an alarm or transmitting a diagnosis result of whether or not the sensing electrodes (01, 02) are disconnected to a control server. According to claim 1,
The control unit (05) further includes a function for alternately executing a leak detection mode and a disconnection diagnosis mode of the sensing electrodes (01, 02). The leak detection sensor having a disconnection diagnosis function of the sensing electrodes (01, 02) according to claim 4, wherein a cycle of alternately executing the leak detection mode and the disconnection diagnosis mode of the sensing electrodes (01, 02) is variably controlled according to the cumulative use time of the leak detection sensor.