KR101541719B1 - Apparatus for protection potential multiguard of gas pipe line and method for remote control of that - Google Patents

Abstract

The present invention relates to a system potential multi-monitoring apparatus for a gas pipeline and a remote control method thereof, and more particularly, to a system potential multi-monitoring apparatus for a gas pipeline that includes a medium pressure monitoring line drawn out from a medium pressure pipeline to a remote monitoring apparatus of a constant- A low-pressure monitoring line drawn out from the low-pressure pipe to the remote monitoring device of the constant-pressure facility and connected or short-circuited; Pressure monitoring line and a low-pressure monitoring line to selectively connect or disconnect the intermediate-pressure monitoring line and the low-pressure monitoring line to monitor the insulation state of the intermediate-pressure piping and the low-pressure piping, and the abnormality of the medium-pressure piping or the low-pressure piping. It is possible to monitor the potential in the state where the monitoring lines of the medium-pressure piping and the low-pressure piping are connected to determine whether the insulation facility is insulated from the piping, and to selectively perform the method potential monitoring of the medium- It is possible to perform the inspection and maintenance by the technique of compressing the cause point more quickly by reducing the defective range when defects such as occurrence of coating damage of metal pipes, Is provided.

Description

TECHNICAL FIELD [0001] The present invention relates to a method for monitoring multiple potentials of a gas pipeline and a remote control method thereof,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a system potential multi-monitoring apparatus for a gas pipeline and a remote control method thereof, and more particularly to a system potential multi-monitoring apparatus for a gas pipeline capable of selectively monitoring the state of a medium- To a remote control method.

Generally, city gas is supplied from a city gas supply facility through a pipeline to a final demand site. For this purpose, a city gas supply facility sends a high pressure (medium pressure) pressure and a low pressure pressure supply .

Here, most of the static pressure equipment is operated as unmanned, and a remote terminal unit (RTU) is installed to monitor the operation state of the static pressure equipment.

1 is a block diagram schematically showing the construction of a static pressure equipment having a remote monitoring apparatus. As shown in the figure, a static pressure facility 10 is provided between a medium pressure pipe 20 and a low pressure pipe 30, Is installed in an electrically insulated state by insulating flanges (24, 34), and is made up of components such as valves, filters, emergency shutdown devices, and pressure regulators.

The RTU 50 monitors the operating state of the static pressure facility 10 and measures the gas pressure of the inlet side medium pressure pipe 20 and controls the pressure of the outlet side low pressure pipe 20 30), the gas flow is automatically shut off under the abnormal pressure, the gas leakage is detected, and in particular, the function of detecting the corrosion of the pipe or the interference (contact) with the other facilities is also performed .

That is, when the material supplied through the gas piping leaks to the outside, it causes human injury or environmental pollution, so that the remote monitoring unit (RTU) 50 causes an abnormality on the surface of the gas piping 20, 30 It is necessary to confirm the situation and prevent the accident from occurring.

On the other hand, in the gas piping buried in the ground, corrosion protection is performed in order to extend the life of the piping. In this gas piping method, polyethylene coated steel pipe coated with polyethylene in the metal piping is mainly used.

In this case, in order to prevent the corrosion of the gas pipe at the damaged part in case of coating damage, the electric method is applied. In the electric method, the sacrificial anode method and the external power method are used. Here, the sacrificial anode method is a method in which a metal having a tendency to ionize is electrically connected to a buried pipe such as magnesium or the like to be buried in the ground to make the pipe negative, and the external power supply method is a separate stop It is a method to control the method current using an anode embedded in the ground by converting AC power of external KEPCO into DC current.

1, the monitoring lines 22 and 32 are drawn out from the medium-pressure piping 20 and the low-pressure piping 30, respectively, and are connected to each other at a predetermined point 40, and the connected monitoring lines 42 Is connected to the remote monitoring unit (RTU) 50, so that the remote monitoring device 50 always monitored only the medium / low pressure bonding potential.

However, such a conventional current / potential monitoring system of gas pipelines is incapable of measuring the direction and amount of the method current, and it is difficult to quickly locate it when contacting with other facilities, , It takes a lot of time and manpower to identify the cause of the failure.

In other words, even if abnormality currents / potentials are transmitted at any point, such as buried piping entwined like a web in the ground, metal touch in exposed granular pipes, insulation breakdown, occurrence of damaged parts, etc., The piping could not be found quickly.

Therefore, even if various abnormalities occur on the side of the gas piping system in the related art, in order to derive the cause in the field, it is impossible to grasp the phenomenon after direct manipulation of a large number of insulation facilities, There is a time, manpower consumption and safety problems due to unnecessary field movements and inspections such as measuring the potential at the box, checking the huge amount of intercorrelation condition, and sometimes conducting the electric current through excavation.

The conventional method of monitoring the state of the gas piping according to the related art includes the 'remote monitoring and safety management system for the underground piping condition' of Korean Patent Registration No. 10-0630639 or the 'underground piping' of the Korean Patent Registration No. 10-0672202 State remote monitoring system ', and the like are known.

SUMMARY OF THE INVENTION The present invention has been made in view of the above-mentioned problems, and it is an object of the present invention to provide a remote monitoring device for a static pressure facility, which is capable of directly connecting separately a monitoring line of a medium pressure pipe and a low pressure pipe, The present invention aims to provide a device capable of monitoring multiple gas pipes at a single connection point of a medium / low pressure pipe and a remote control method thereof.

That is, the present invention monitors the potential in the state where the monitoring lines of the medium-pressure piping and the low-pressure piping are connected to determine whether or not the insulation facility is insulated from the piping, the method potential monitoring of the medium- , It is possible to perform inspections and maintenance more quickly, such as checking the insulation areas and stepping blocks to reduce the extent of defects such as corrosion of piping as well as control of insulation equipment, The present invention provides a method for monitoring the potential of a gas pipeline and a remote control method thereof.

According to another aspect of the present invention, there is provided an apparatus for monitoring the potential of a gas pipeline, comprising: a medium pressure pipe for supplying gas from a gas supply source; a static pressure device for lowering a pressure of gas supplied from the medium pressure pipe to a low pressure; Pressure monitoring line which is connected to or disconnected from the medium pressure piping to the remote monitoring device of the constant-pressure facility, and a low pressure pipeline that supplies low-pressure gas whose pressure has been lowered by the static pressure facility to the gas demanding place; Pressure monitoring line drawn out from the low-pressure pipe to the remote monitoring device of the constant-pressure facility and connected or short-circuited; Pressure monitoring line and a low-pressure monitoring line to selectively connect or disconnect the intermediate-pressure monitoring line and the low-pressure monitoring line to monitor the insulation state of the intermediate-pressure piping and the low-pressure piping and to monitor the abnormality of the medium-pressure piping or the low-pressure piping.

In this case, the medium pressure monitoring line may include: a first medium pressure monitoring line connected from the medium pressure line; A second intermediate pressure monitoring line branched from the first intermediate pressure monitoring line and connected to the second intermediate pressure monitoring line; And a third intermediate pressure monitoring line branched from the second intermediate pressure monitoring line, wherein the low pressure monitoring line comprises: a first low pressure monitoring line connected from the low pressure line; A second low-voltage monitoring line branched from the first low-pressure monitoring line; And a third low-voltage monitoring line branched from the second low-pressure monitoring line.

The relay unit may further include a first monitoring unit that selectively connects or disconnects the first intermediate-voltage monitoring line, the first low-voltage monitoring line, the second intermediate-voltage monitoring line, and the second low- A relay switch; And a second relay switch for selectively connecting or short-circuiting the second intermediate-voltage monitoring line, the second low-voltage monitoring line, the third intermediate-voltage monitoring line and the third low-voltage monitoring line in accordance with a control signal of the remote monitoring apparatus Preferably, the first relay switch includes a first switch for connecting or short-circuiting the first intermediate-pressure monitoring line; A second switch for connecting or short-circuiting the first low-voltage monitoring line; A third switch for connecting or short-circuiting the second intermediate-pressure monitoring line; And a fourth switch for connecting or disconnecting the second low-pressure monitoring line, wherein the second relay switch includes: a first switch for connecting or short-circuiting the second intermediate-pressure monitoring line; A second switch for connecting or short-circuiting the second low-voltage monitoring line; A third switch for connecting or short-circuiting said third intermediate-pressure monitoring line; And a fourth switch for connecting or short-circuiting the fourth central monitoring line.

The second intermediate-pressure monitoring line is branched from the first intermediate-pressure monitoring line at the front end side of the first relay switch, and the third intermediate-pressure monitoring line is branched from the second intermediate-pressure monitoring line, Pressure supervisory line is branched at a front end side of the first relay switch, and the third low-voltage surveillance line is branched from the first low- Is branched from the second low-voltage monitoring line, and is branched from the first relay switch and the second relay switch.

In this case, when monitoring the potential of the medium-pressure piping and the low-pressure piping, the first relay switch is controlled so that the first switch connects the first intermediate-pressure monitoring line, and the second switch connects the first intermediate- The third switch short-circuits the second intermediate-voltage monitoring line, and the fourth switch short-circuits the second low-voltage monitoring line.

Further, when the potential of the low-pressure pipe is monitored, the first relay switch is controlled to short-circuit the first intermediate-pressure monitoring line, and the second switch short-circuits the first intermediate-pressure monitoring line , The third switch connects the second intermediate-pressure monitoring line, the fourth switch connects the second low-voltage monitoring line, and controls the second relay switch, and the first switch connects the second low- Voltage monitoring line, the second switch connects the second low-voltage monitoring line, the third switch short-circuits the third intermediate-pressure monitoring line, and the fourth switch short-circuits the third low-voltage monitoring line .

In this case, it is preferable that the first switch of the second relay switch is connected to the second intermediate-pressure monitoring line so as to be grounded.

When monitoring the potential of the medium-pressure pipeline, the first relay switch is controlled so that the first switch short-circuits the first intermediate-pressure monitoring line, and the second switch short-circuits the first intermediate-pressure monitoring line , The third switch connects the second intermediate-pressure monitoring line, the fourth switch connects the second low-voltage monitoring line, and controls the second relay switch, and the first switch connects the second low- Voltage monitoring line, the second switch short-circuits the second low-voltage monitoring line, the third switch connects the third middle-pressure monitoring line, and the fourth switch connects the third low-voltage monitoring line .

In this case, it is preferable that the fourth switch of the second relay switch connects the third intermediate-pressure monitoring line to ground.

Meanwhile, a remote control method in a method for monitoring multiple potentials of a gas piping according to the present invention is a method for monitoring a potential of a medium-pressure piping and a low-pressure piping, which form a gas piping, , And the potential of the low-pressure pipe is selectively subjected to multiple monitoring.

In this case, normally, the potential of the medium-pressure piping and the low-pressure piping is monitored, and when the abnormality signal is received by the remote monitoring apparatus during the monitoring, It is preferable to judge which of the above-mentioned intermediate-pressure pipe and the low-pressure pipe has a problem.

As described above, according to the method for monitoring multiple potentials of the gas pipeline according to the present invention and the remote control method thereof, the monitoring lines of the medium-pressure piping and the low-pressure piping are individually and directly connected to the remote monitoring apparatus of the static- The gas piping can be monitored in multiple ways.

That is, by monitoring the potentials in the state where the monitoring lines of the medium-pressure piping and the low-pressure piping are connected, whether the insulation installation is insulated from the piping, and selectively monitoring the method potential monitoring of the medium-pressure piping and the method potential monitoring of the low- It is possible to perform inspection and maintenance more quickly by reducing the defective range of defects such as damage of covering of piping as well as control of insulation equipment.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a block diagram schematically showing the construction of an insulation installation of a conventional gas pipeline. FIG.
2 is a block diagram schematically showing the structure of a method for monitoring multiple potentials of gas piping according to the present invention.
FIGS. 3 to 5 are conceptual diagrams illustrating a multiple monitoring method for selecting a monitoring target according to a connection or a short circuit of relay switches according to a control signal in a method for monitoring multiple potentials of gas piping,
3 is a view showing a method of monitoring an insulation state of an insulation installation in a normal state.
4 is a diagram showing a method for monitoring a process potential of a low-pressure pipe;
5 is a diagram showing a method for monitoring a process potential of a medium-pressure pipe;

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 2 is a block diagram schematically showing the structure of a method for monitoring multiple potentials of a gas pipeline according to the present invention. FIGS. 3 to 5 are diagrams for explaining a method for monitoring the connection or short- FIG. 2 is a conceptual diagram showing a multiple monitoring method for selecting a monitoring target according to FIG.

In the following description of the embodiment of the present invention, repetitive description of the same parts as those of the conventional art will be omitted.

2, the multiple monitoring apparatus for a gas piping according to the present invention includes a medium pressure piping 110 for supplying gas from a gas supply source, and a low pressure piping 110 for supplying a gas supplied from the medium pressure piping 110 at a low pressure Pressure piping 120 for supplying a low-pressure gas whose pressure has been lowered by the constant-pressure facility 100 to a gas consumer.

The monitoring lines 112 and 122 are connected to the remote monitoring apparatus 130 through the intermediate pressure piping 110 and the low pressure piping 120. The monitoring lines 112 and 122 are connected or disconnected by the relay unit 150, Pressure piping 110 and the low-pressure piping 120 or to selectively monitor the method potential of the medium-pressure piping 110 or the method potential of the low-pressure piping 120,

Reference numeral 114 denotes an insulation flange for insulating the intermediate-pressure piping 110 from the insulation installation 100, and 124 is an insulation flange for insulating the low-pressure piping from the insulation installation.

The relay unit 150 includes a first relay switch 200 and a second relay switch 300 and operates according to a selected control signal to control the process potential of the intermediate pressure pipe 110 and the low pressure pipe 120, The system potential of the piping 110 and the system potential of the low-pressure piping 120 are selectively monitored.

The medium pressure monitoring line 112 connected to the relay unit 150 of the remote monitoring apparatus 130 is connected to the remote monitoring apparatus 130 by the operation of the first relay switch 200, And the first relay switch 200 is branched from the front end of the first relay switch 200 and connected to the first intermediate pressure monitoring line 112a. A second medium voltage monitoring line 112b which is connected or short-circuited or grounded by the remote monitoring device 130 by the second relay switch 300 and a second medium voltage monitoring line 112b which is branched and connected from the second medium voltage monitoring line 112b, And a third intermediate pressure monitoring line 112c branched from the relay switch 200 and the second relay switch 300 and connected or short-circuited to the far-sight monitoring device 130 by the second relay switch 300 .

The low voltage monitoring line 122 connected from the low pressure pipe 120 to the relay unit 150 of the remote monitoring apparatus 130 is connected to the remote monitoring apparatus 130 by the operation of the first relay switch 200, And the first relay switch 200 is branched from the first relay switch 200 and branched from the first low voltage monitoring line 122a and connected to the first relay switch 200. The first relay switch 200 is connected to the first relay switch 200, A second low voltage monitoring line 122b connected to or short-circuited with the far-sight monitoring device 130 by the second relay switch 300 and a second low-voltage monitoring line 122b branched from the second low-voltage monitoring line 122b, And a third low-voltage monitoring line 122c branched from the first relay switch 200 and the second relay switch 300 and short-circuited or grounded by the second relay switch 300.

The first relay switch 200 includes a first switch 210 connecting or shorting the first medium voltage monitoring line 112a to the farther monitoring device 130 and a second switch 210 connecting the first low voltage monitoring line 122a to the far- A third switch 230 connecting or disconnecting the second medium voltage monitoring line 112b from the farther monitoring apparatus 130 and a second switch 220 connecting or disconnecting the second medium voltage monitoring line 112b from the farther monitoring apparatus 130, And a fourth switch 240 for connecting or disconnecting the remote controller 122b to / from the remote monitoring apparatus 130.

The second relay switch 300 also includes a first switch 310 for selectively grounding the second medium voltage monitoring line 112b and a second switch 310 for connecting the second low voltage monitoring line 122b to the remote monitoring apparatus 130 The third switch 330 for connecting or disconnecting the third medium voltage monitoring line 112c from the farther monitoring device 130 and the third low voltage monitoring line 122c are selectively grounded And a fourth switch 340.

The monitoring line 112 of the medium pressure piping 110 and the monitoring line 122 of the low pressure piping 120 are connected or disconnected from the remote monitoring apparatus 130 by the relay unit 150 having the above- The process potential of the medium-pressure piping 110 and the low-pressure piping 120 and the process potential of the medium-pressure piping 110 or the low-pressure piping 120 will be described as follows.

<Regular monitoring - Isolation of medium-pressure piping and low-pressure piping and monitoring method potential>

3, the potential of the medium-pressure piping 110 and the low-pressure piping 120 is monitored during normal operation, and the static-pressure facility 100 is insulated from the medium-pressure piping 110 and the low-pressure piping 120 Pressure piping 110 and the low-pressure piping 120 are monitored.

In this case, among the first relay switches 200, the first switch connects the first medium-pressure monitoring line 112a to connect the medium-pressure piping 110 to the remote monitoring apparatus 130, and the second switch connects the medium- Pressure piping 110 and the low-pressure piping 120 are monitored by connecting the low-pressure piping 120 and the remote monitoring apparatus 130 by connecting the monitoring line 122a.

The third switch 230 and the fourth switch 240 of the first relay switch 200 are connected to the remote monitoring device 130 via the second medium voltage monitoring line 112b and the second low voltage monitoring line 122b, And short-circuiting is performed.

Here, the second relay switch 300 is configured such that the third switch 330 and the fourth switch 340 among the first relay switch 200 are connected to the second intermediate-voltage monitoring line 112b and the second low- 122b are short-circuited with the far-sight monitoring device 130, the position can be any position.

In this state, when an abnormal signal due to corrosion or the like among the medium-pressure piping 110 or the low-pressure piping 120 is transmitted to the far-field monitoring apparatus 130, the operator selects one of the medium-pressure piping 110 or the low- , The potential of the medium-pressure piping 110 or the low-pressure piping 120 may be selectively monitored in order to determine which piping has an abnormality.

<Low pressure piping system status monitoring>

4, when an operation signal is applied to the first relay switch 200 to sense the state of the low-pressure pipe 120, the first switch 210 and the second switch 220 are turned on, Voltage monitoring line 122a are short-circuited with the far-field monitoring device 130 and the third switch 230 and the fourth switch 240 are connected to the remote monitoring device 130, respectively, Voltage monitoring line 112b and the second low-voltage monitoring line 122b are connected to each other.

At this time, among the second relay switches 300, the first switch 310 grounds the second intermediate-voltage monitoring line 112b, the second switch 320 connects the second low-voltage monitoring line 122b, The third switch 330 shorts the third medium voltage monitoring line 112c and shorts the third low voltage monitoring line 122c so that the third low voltage monitoring line 122c is not grounded.

Accordingly, the current transmitted from the medium-pressure piping 110 is not transmitted to the far-sight monitoring device 130 by the short-circuit of the first switch 210 of the first relay switch 200, The third switch 230 of the first relay switch 200 and the first switch 310 of the second relay switch 300 are grounded and the current through the third intermediate voltage monitoring line 112c 2 relay switch 300 is not transmitted to the far-sight monitoring device 130 due to the third switch 330 short-circuit.

On the contrary, the current transmitted from the low-pressure pipe 120 is not directly transmitted to the far-sight monitoring device 130 by the short-circuit of the second switch 220 of the first relay switch 200, To the remote monitoring device 130 via the fourth switch 240 of the first relay switch 200 and the second switch 320 of the second relay switch 300 through the remote control device 130, Only the potential of the low-pressure pipe 120 is monitored.

Thus, it is possible to detect the abnormality such as corrosion of the low-pressure pipe 120 by sensing the abnormality signal while monitoring only the potential of the low-pressure pipe 120.

<Status monitoring of medium pressure piping system>

When monitoring the potential of the medium-pressure piping 110 in the state in which the potential of the low-pressure piping 120 is monitored by the above-described control, As shown, the second relay switch 300 may be operated.

That is, the first relay switch 200 operates only the second relay switch 300 in a state where the first relay switch 200 is left in the state of monitoring the potential of the low-pressure pipe 120 so that the first switch 310 is connected to the second intermediate- The second switch 320 shorts the second low-voltage monitoring line 122b and the third switch 330 connects the third middle-pressure monitoring line 112c to the far-sight monitoring device 130, and the fourth switch 340 allows the third low-voltage monitoring line 122c to be grounded.

Therefore, the current transmitted from the low-pressure pipe 120 is not transmitted to the far-sight monitoring device 130 by the short-circuit of the second switch 220 of the first relay switch 200, but is transmitted through the second low- The fourth switch 240 of the first relay switch 200 is grounded via the third low voltage monitoring line 122c and the fourth switch 340 of the second relay switch 300, The current through the line 122b is also not transmitted to the far-sight monitoring apparatus 130 due to the short-circuit of the second switch 320 of the second relay switch 300. [

Conversely, the current transmitted from the medium-pressure piping 110 is not directly transmitted to the far-sight monitoring apparatus 130 by the short-circuit of the first switch 210 of the first relay switch 200, To the remote monitoring device 130 through the third switch 230 of the first relay switch 200 and the third switch 330 of the third intermediate monitoring line 112c and the second relay switch 300 As a result, the remote monitoring apparatus 130 monitors only the potential of the medium-pressure piping 110.

In this way, it is possible to detect the abnormality of the medium-pressure piping 110 by sensing the abnormality signal in a state in which only the potential of the medium-pressure piping 110 is monitored.

Therefore, in the normal monitoring state, only the insulation state of the insulation installation 100 and the medium / low pressure bonding potential are monitored, and when the abnormal signal is transmitted, the first relay switch 200 and the second relay switch 300 are selectively operated It is possible to separately monitor the system potentials of the low-pressure piping 120 or the medium-pressure piping 110. At this time, when abnormality signals are not received at the time of monitoring the potential of the low-pressure piping 120, When the signal is received, it is determined that a problem has occurred in the medium-pressure piping 110 among all the gas piping, so that the range of maintenance can be reduced by half.

On the other hand, when an abnormality signal is not received during the potential monitoring of the medium-pressure piping 110 and an abnormal signal is received during the potential monitoring of the low-pressure piping 120, it is assumed that a problem has occurred in the low-pressure piping 120 It is obvious that the range of maintenance can be reduced by half.

Although it was a simple explanation to help understanding, it has been confirmed that the method potential of the region where there is no abnormality is restored to normal by separating by the control of the medium pressure or low pressure piping in the case of the external power method region which is frequently utilized, It is possible to derive the range of the occurrence area.

The technical ideas described in the embodiments of the present invention as described above may be independently performed, or may be implemented in combination with each other. While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is evident that many alternatives, modifications, and variations will be apparent to those skilled in the art. It is possible. Accordingly, the technical scope of the present invention should be determined by the appended claims.

100: Insulation equipment 110: Medium pressure piping
112: medium pressure monitoring line 112a: first intermediate pressure monitoring line
112c: third intermediate pressure monitoring line 114: insulating flange
120: low pressure piping 122: low pressure monitoring line
122a: first low-voltage monitoring line 122b: second low-voltage monitoring line
122c: third low-voltage monitoring line 124: insulation flange
130: remote monitoring device 150: relay part
200: first relay switch 210: first switch
220: second switch 230: third switch
240: fourth switch 300: second relay switch
310: first switch 320: second switch
330: third switch 340: fourth switch

Claims (13)

Pressure piping for supplying gas from a gas supply source, a constant-pressure piping for lowering the pressure of the gas supplied from the medium-pressure piping to a low pressure, and a low-pressure piping for supplying a low- ,
A medium pressure monitoring line which is connected to or disconnected from the medium pressure piping to a remote monitoring apparatus of the static pressure facility;
Pressure monitoring line drawn out from the low-pressure pipe to the remote monitoring device of the constant-pressure facility and connected or short-circuited;
Further comprising a relay unit for monitoring an insulation state of the intermediate-pressure piping and the low-pressure piping and monitoring the abnormality of the medium-pressure piping or the low-pressure piping by selectively connecting or disconnecting the medium-pressure monitoring line and the low-pressure monitoring line. Method potential multiple monitoring device.
The method according to claim 1,
The medium pressure monitoring line includes:
A first intermediate pressure monitoring line connected from the intermediate pressure pipe;
A second intermediate pressure monitoring line branched from the first intermediate pressure monitoring line and connected to the second intermediate pressure monitoring line;
And a third intermediate pressure monitoring line branched from and connected to the second intermediate pressure monitoring line,
The low-
A first low-pressure monitoring line connected from the low-pressure pipe;
A second low-voltage monitoring line branched from the first low-pressure monitoring line;
And a third low-pressure monitoring line branched from the second low-pressure monitoring line and connected to the third low-pressure monitoring line.
3. The method of claim 2,
The relay unit includes:
A first relay switch for selectively connecting or disconnecting the first intermediate-voltage monitoring line, the first low-voltage monitoring line, the second intermediate-voltage monitoring line, and the second low-voltage monitoring line in accordance with a control signal of the remote monitoring apparatus;
And a second relay switch for selectively connecting or shorting the second intermediate-voltage monitoring line, the second low-voltage monitoring line, the third intermediate-voltage monitoring line and the third low-voltage monitoring line in accordance with the control signal of the remote monitoring apparatus Wherein the gas pipeline is connected to the system.
The method of claim 3,
Wherein the first relay switch comprises:
A first switch for connecting or short-circuiting the first intermediate-pressure monitoring line;
A second switch for connecting or short-circuiting the first low-voltage monitoring line;
A third switch for connecting or short-circuiting the second intermediate-pressure monitoring line;
And a fourth switch for connecting or short-circuiting the second low-voltage monitoring line,
Wherein the second relay switch comprises:
A first switch for connecting or short-circuiting the second intermediate-pressure monitoring line;
A second switch for connecting or short-circuiting the second low-voltage monitoring line;
A third switch for connecting or short-circuiting said third intermediate-pressure monitoring line;
And a fourth switch for connecting or short-circuiting said third low-pressure monitoring line.
The method of claim 3,
And the second intermediate-voltage monitoring line is branched at the front end side of the first relay switch in the first intermediate-pressure monitoring line,
Wherein the third intermediate pressure monitoring line is branched from the second intermediate pressure monitoring line and branched from the first relay switch and the second relay switch.
The method of claim 3,
The second low-voltage monitoring line is branched at the first end of the first relay switch in the first low-voltage monitoring line,
And the third low-pressure monitoring line is branched from the second low-pressure monitoring line, and branched from the first relay switch and the second relay switch.
5. The method of claim 4,
In monitoring the potentials of the medium-pressure piping and the low-pressure piping,
The first switch controls the first relay switch to connect the first intermediate-pressure monitoring line, the second switch connects the first low-voltage monitoring line,
Wherein the third switch short-circuits the second intermediate-voltage monitoring line, and the fourth switch short-circuits the second low-voltage monitoring line.
5. The method of claim 4,
In monitoring the potential of the low-pressure pipe,
The first switch controls the first relay switch to short-circuit the first intermediate-pressure monitoring line, the second switch short-circuits the first low-voltage monitoring line,
The third switch connects the second intermediate-voltage monitoring line, the fourth switch connects the second low-voltage monitoring line,
The second switch is connected to the second low-voltage monitoring line, and the second switch is connected to the second low-voltage monitoring line,
Wherein the third switch short-circuits the third intermediate-voltage monitoring line, and the fourth switch short-circuits the third low-voltage monitoring line.
9. The method of claim 8,
And the first switch of the second relay switch is connected to the second intermediate-pressure monitoring line so as to be grounded.
5. The method of claim 4,
In monitoring the potential of the medium-pressure piping,
The first switch controls the first relay switch to short-circuit the first intermediate-pressure monitoring line, the second switch short-circuits the first low-voltage monitoring line,
The third switch connects the second intermediate-voltage monitoring line, the fourth switch connects the second low-voltage monitoring line,
The second switch controls the second relay switch to short-circuit the second intermediate-voltage monitoring line, the second switch short-circuits the second low-voltage monitoring line,
Wherein the third switch connects the third intermediate pressure monitoring line and the fourth switch connects the third low pressure monitoring line.
11. The method of claim 10,
And the fourth switch of the second relay switch is connected to the third intermediate-pressure monitoring line to ground the gas pipeline.
A method for monitoring multiple potentials of a gas pipeline according to any one of claims 1 to 11, wherein the potential of the medium-pressure piping and the low-pressure piping, the potential of the medium-pressure piping, and the potential of the low- And the remote control is performed to perform multiple monitoring.
13. The method of claim 12,
Pressure piping and the low-pressure piping are selectively monitored during the monitoring by the relay unit during reception of an abnormal signal to the remote monitoring apparatus during the monitoring, Pressure piping and the low-pressure piping, and determines which of the intermediate-pressure piping and the low-pressure piping has a problem.

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