KR20110043984A - Electrolytic protection surge protector for supervisory control and data acquisition system and remote terminal unit - Google Patents

Abstract

PURPOSE: An electrolytic protection surge protector for supervisory control, a data acquisition system and a remote terminal unit are provided to reduce the repair and maintenance costs by preventing the damage of a disc sensor from the overvoltage/current. CONSTITUTION: A disc sensor is electrically connected to a buried metallic pipeline for LNG through an electric wire(460). An overvoltage absorption circuit(600) and a voltage/current restriction circuit(650) is inserted into the front end of the measurement unit of a signal converter(450). The overvoltage absorption circuit and the voltage/current restriction circuit restricts the flow of the voltage over the voltage level allowed by a measurement unit, and comprises a current restriction element(520), a surge absorption element(530) and voltage restriction elements(540,550).

Description

Electrical Surge Protector for City Gas Remote Monitoring System {Electrolytic Protection Surge Protector for Supervisory Control and Data Acquisition System and Remote Terminal Unit}

The present invention relates to a surge protector of a remote monitoring unit (RTU) of a remote terminal unit of a city gas constant pressure facility for supplying gas through a buried pipe to supply pressure to a low pressure gas at a low pressure in a city gas supply facility. In particular, the present invention relates to an electrical surge protector for a city gas remote monitoring device for protecting the remote monitoring device from abnormal transient voltage / current caused by lightning or surge introduced through a buried pipe.

In general, city gas is supplied from a city gas supply facility to a final demand destination through a small pipe diameter, and the city gas supply facility is sent at a high pressure (medium pressure) and then a static pressure facility near the demand destination. To reduce pressure at low pressure. For this reason, there is a possibility that abnormalities may occur in the process of reducing the pressure to low pressure, and in order to prepare for such a case, a safety device such as an automatic shutoff of gas supply is provided.

At present, most of the static pressure facilities are operated unattended. Therefore, in order to monitor the operation state of such a static pressure installation, the remote monitoring apparatus is provided. The general configuration of the hydrostatic installation and remote monitoring system is as follows.

1 is a block diagram of a remote monitoring device of a typical city gas constant pressure equipment.

As shown in FIG. 1, the static pressure facility 100 is installed at the rear end of the insulating spacer 110 of the medium pressure pipe 200, the valve 120, the filter 130, the emergency shutoff device 140, and the pressure regulator. 150 and the valve 160 are connected in order, and the low pressure pipe 250 is electrically insulated by the insulating spacer 110.

Far-away monitoring device 400 is installed to monitor the operating state of the static pressure equipment 100, a medium pressure transmitter 410 for measuring the inlet gas pressure supplied to the static pressure equipment 100, and a pressure regulator ( Low pressure transmitter 420 for measuring the outlet gas pressure decompressed through 150, the operation sensor 430 of the emergency shutoff device consisting of an emergency shutoff valve for automatically blocking the flow of gas at the time of abnormal pressure (when the pressure rises) , The gas leakage alarm 440 for detecting the leakage of gas in the constant pressure facility 100, the pipe potential measurement signal converter 450 for detecting the corrosion of the pipe and interference (contact) of other facilities. .

According to the remote monitoring device 400 configured as described above, the insulation spacer 110 may maintain the insulation state with the buried pipes 200 and 250, but the signal transducer 450 for measuring the pipe potential is used for pipes and wires. Since the connection state is maintained through 460, the pipe cannot be protected from abnormal conditions of the pipe due to lightning or surge.

For example, the remote monitoring device 400 is a precision electronic device composed of a measurement circuit, a microprocessor, a communication circuit, and the like. The remote monitoring device 400 may cause a malfunction due to noise or an abnormal voltage, and may be caused by the destruction of the system by a shock current caused by a lightning strike or a surge. It may be followed.

FIG. 2 is a perspective view illustrating a surge voltage inflow path due to lightning that may occur in a buried city gas pipe. As buried city gas metal pipes (200, 250; hereinafter referred to as 'burying pipes'), polyethylene coated steel pipes coated with polyetherene on the metal pipes 210 to prevent corrosion are mainly used. have. In this case, in order to prevent corrosion of the metal pipe of the damaged part during coating damage, an electric method is performed. As the electric method, a sacrificial anode method, which is mainly a corrosion prevention method using a sacrificial anode, is used. The sacrificial anode method is to electrically connect a buried pipe to a buried pipe by electrically connecting a metal having a higher ionization tendency than a metal such as magnesium 280 so as to make the pipe cathode.

The test box 270 is installed on the ground as a measuring point for testing the electrical potential of the buried pipe. For example, in the sacrificial anode method using the ground as an electrolyte when a momentary surge voltage occurs due to a lightning strike at the “point A” of FIG. 2, the surge voltage is absorbed through the ground to the coated damage site or the magnesium 280 electrode. Electricity is discharged to the lower potential through the metal pipe, which is a conductor, which causes abnormal pipe potential at the "B point". Therefore, there is a high risk of causing the failure of the remote monitoring apparatus.

As described above, the signal converter 450 and the remote monitoring device 400 connected through the embedded metal pipes 200 and 250 and the wire 460 may not be protected from lightning or surge. In addition, since surge voltage is absorbed through the ground, and electricity flows out to the lower potential through the metal pipe, which is a conductor, it shows abnormal pipe potential at a point other than the point where the instantaneous surge voltage is generated by lightning strike. There is also a risk of failure.

The present invention has been made to solve the above problems, the transient voltage of the buried pipe to protect the remote monitoring device from abnormal state of the buried pipe due to the inflow of lightning or surge in the far monitoring device of the city gas constant pressure facility. The purpose is to provide a surge protector capable of limiting the current.

Electrical type surge protector of the city gas remote monitoring apparatus according to the present invention for achieving the above object is inserted into the front end of the measuring unit of the remote monitoring device or the signal converter electrically connected through a pipe and an electric wire, An overvoltage absorbing circuit and a voltage / current limiting circuit for preventing a voltage exceeding an allowable input from passing through are provided, wherein the protection range in operation of the protector is determined by the voltage difference between the pipe and the ground.

The surge protector according to the present invention, in the schematic diagram of the electrical surge protector of the city gas remote monitoring apparatus according to an embodiment of the present invention of Figure 3, the current limiting element 520, the surge absorbing element 530, Comprising a voltage limiting element (540, 550), the high surge voltage induced in the pipe 200 flows into the surge protector of the present invention through the wire 460, the current limiting element of the primary protection circuit 600 The surge component of the high voltage and high current is filtered through the surge absorbing element 530 and the ground 580 connected in series with the 520, and the secondary protection circuit 650 is connected to a remote monitoring device such as a signal transformer 450. It acts as a protector to have a constant voltage characteristic so that voltages above the input allowable voltage cannot pass.

According to the electrical type surge protector of the city gas far monitoring device according to the present invention, it is possible to prevent damage to the far field monitoring device from transient voltage / current caused by lightning or surge flowing into the buried city gas pipe. Maintenance costs can be reduced and safety accidents can be prevented.

Hereinafter, with reference to the drawings will be described in detail the electrical surge protector for the city gas remote monitoring apparatus according to an embodiment of the present invention.

4 is a circuit diagram of an electrical surge protector for a city gas remote monitoring apparatus according to an embodiment of the present invention, and FIG. 5 is a graph showing a change in output according to an input in an embodiment of the present invention.

First, as shown in Figure 4, in the circuit diagram of the electrical surge protector of the remote monitoring apparatus according to an embodiment of the present invention, the input terminal 710 of the surge protector 700 is buried pipe ( 200 and 250 may be connected to the wire 460. The high surge voltage introduced into the buried pipes 200 and 250 is input to the input terminal 710 of the surge protector 700 through the connected wire 460, the surge protector 700 of the present invention is the TNR element 730 And the TVS element 750 are combined to prevent a voltage above a certain voltage from passing through the output terminal 760. The TNR device 730 connected in series with the R1 resistor 720 is intended to absorb high surges firstly, where the TNR device 730 rapidly increases the internal resistance when the voltage between both terminals of the device rises above a certain voltage. This reduces the short-circuit state, thereby bringing the voltage across the device closer to "0 (V)." The role of the R1 resistor 720 is to limit the current, and when the TNR element 730 is shorted, it is used to prevent the instantaneous current of the circuit from rising to destroy the TNR element.

For example, assuming that a surge voltage of 100,000 volts is applied to the protection circuit, if the R1 resistor 720 is 10 kilo ohms, then from "Ohm's law (I = V / R)" The current can be reduced to 1 / 10,000 to protect the device.

Further, by further installing a R2 resistor 740 and a TVS element 750 at the rear end of the TNR element 730, a series circuit of the R2 resistor 740 and the TVS element 750 is further provided between ground and Protection from transient voltages outside the characteristic range of the TNR element 730 is possible. The TVS device 750 prevents the voltage between the devices from rising above a predetermined voltage by using the characteristics of the constant voltage diode. The role of the R2 resistor 740 is to limit the current, by limiting the rise of the internal current by the constant voltage characteristics of the TVS element 750 even in the transient voltage, it can perform the function of the electrical surge protector.

In the configuration of the protector as described above, for example, assuming that the surge voltage is about 100,000 volts (V), and the pass voltage can be limited to 10 volts (V), the R1 resistance 720 is 10 kilos. It is preferable that the ohmic and the R2 resistor 740 are suitable for 1 kiloohm, and the TVS element 750 selects a component having a constant voltage characteristic of 10 volts (V). The signal input of the remote monitoring device 400 or the signal converter 450 is within 10 volts (V), because the electrical potential of the buried pipe does not affect other facilities, and in most cases 5 volts. It is preferable to design and construct below (V).

5 is a graph showing a change in the output 890 according to the input 800 in an embodiment of the present invention, when the surge voltage flows from the pipe, the output after passing through the electrical surge protector of the present invention ( The waveform of 890 is shown graphically. It can be seen that the protective function is performed at a transient voltage of more than the allowable input voltage (protection range; 850) of the remote monitoring device or the signal converter.

6 is a block diagram illustrating an example in which an electrical surge protector of a remote monitoring apparatus according to an embodiment of the present invention is actually applied. Piping 200, 250 is connected to the electrical surge protector 500 of the remote monitoring device of the present invention through the wire 460, the surge protector 500 is connected to the signal converter 450, the signal converter ( 450 may be connected to the remote monitoring device 400. At this time, it is effective to use the ground power source 480 of the remote monitoring device 400 and the ground 480 of the surge protector 500 in common.

In the above, the electrical surge protector of the city gas remote monitoring apparatus according to an embodiment of the present invention has been described in detail. For reference, as shown in Figure 3, according to the configuration of the electrical type surge protector of the city gas remote monitoring device of the present invention, it is possible to reliably protect the remote monitoring device from abnormal voltage caused by lightning or surge flowing from the buried pipe. It can be seen that.

The surge protector of the present invention can prevent damage from transient voltage / current caused by lightning and surge flowing into the buried metal pipe as well as the electric system of the city gas remote monitoring device, and also reduces maintenance costs. Of course, it can be applied to various fields that can prevent safety accidents.

1 is a block diagram of a remote monitoring device of a typical city gas constant pressure equipment.

2 is a perspective view illustrating a surge voltage inflow path due to lightning that may occur in a buried city gas pipe.

Figure 3 is a block diagram of an electrical surge protector of the remote monitoring device according to an embodiment of the present invention.

4 is a circuit diagram of an electrical surge protector of a remote monitoring apparatus according to an embodiment of the present invention.

5 is a graph illustrating a change in output according to an input in an embodiment of the present invention.

6 is a block diagram illustrating an example in which an electrical surge protector of a remote monitoring apparatus according to an embodiment of the present invention is actually applied.

Claims (2)

As an electric surge protector of the city gas remote monitoring device, Inserted into the front end of the measuring unit of the remote monitoring device 400 or the signal converter 450 that is electrically connected through the buried city gas pipes 200 and 250 and the wire 460, the voltage more than the allowable voltage of the measuring unit An overvoltage absorbing circuit (600) and a voltage / current limiting circuit (650) for preventing the passage of electric surge protection device for a city gas remote monitoring device, characterized in that it is provided. According to claim 1, consisting of a current limiting element 520, a surge absorption element 530, a voltage limiting element (540, 550), When the high surge voltage induced in the pipe 200 flows into the surge protector through the wire 460, the surge absorbing element 530 connected in series with the current limiting element 520 of the primary protection circuit 600 and the ground Through 580, the surge component of the high voltage and high current is filtered out, and the secondary protection circuit 650 has a constant voltage characteristic in a remote monitoring device such as a signal converter 450 to prevent a voltage above an input allowable voltage from passing through. Electrical method surge protector, characterized in that.

Images