KR200494171Y1 - a valve position indicator of natural gas Pressure Control Valve - Google Patents

Abstract

According to the present invention, the differential pressure of the upper and lower chambers generated during the operation of the static pressure gauge is indicated by the differential pressure gauge so that the operator can accurately recognize it, and transmits it to the outside through the signal output line, thereby remotely monitoring the opening rate of the static pressure in the field. It relates to an opening degree display device of a static pressure device whose structure is improved so that it can be used.

Description

A valve position indicator of natural gas pressure control valve

The present invention relates to a device for displaying an opening degree of a static pressure machine, and more specifically, the differential pressure gauge indicates the differential pressure between the upper and lower chambers generated during the operation of the static pressure machine so that the operator can accurately recognize it, and through a signal output line By transmitting to the outside, it relates to a static pressure regulator opening rate display device whose structure is improved so that it can remotely monitor the static pressure opening rate in the field.

In general, liquefied natural gas (LNG) imported through an LNG carrier is stored in a storage tank of an onshore base through an unloading facility, is vaporized in the vaporization facility, and is supplied to a governor station.

In the gasification facility, in order to increase the heat exchange efficiency of natural gas and the transport density from the gasification facility to the supply management center, the gas is sent at a high pressure, for example, about 70 bar.

From the supply management office, vaporized gas is supplied to natural gas demanders such as power plants and city gas companies in each branch nationwide.

At this time, the supply management office uses a static pressure facility to depressurize the gasified gas supplied from the gasification facility to a constant pressure and supplies it to the natural gas demander.

As such, the number of static pressure facilities installed across the country reaches 100 (domestic standards), and various types of standardized static pressure facilities are being installed and operated.

In addition, as the demand for natural gas, which is a clean energy, increases, the nationwide gas pipeline network is expanding, and the number of static pressure facilities is continuously increasing.

In general, a static pressure facility is configured by serially connecting a regulator in which pressure reduction is actually performed and a slam shut valve provided at the rear end of the static pressure regulator.

The slam shut valve automatically closes when the pressure at the rear end of the static pressure device increases to more than the set pressure due to the occurrence of an abnormality in the static pressure device, etc., thereby preventing the pressure at the rear end of the static pressure device from rising to a dangerous level.

As the number of small-scale supply flow management stations within the construction increases in accordance with the nationwide expansion of natural gas supply, the number of supply management stations that form a supply volume below the original design flow rate increases. If this is the case, under-measurement and measurement errors may occur. For this reason, intermittent operation is implemented manually by the workers at the management office or the control center.

According to the line pack with the city gas company at each supply management office, there is a problem that workers have to keep an eye on the supply flow rate 24 hours a day according to the need for intermittent operation from time to time. have.

Conventionally, in the case of automatic operation of the metering facility of the static pressure management office, the metering pipe is automatically operated sequentially according to the capacity of each column A, B, and C according to the supply flow rate of the city gas company.

As a prior art related to the conventional natural gas constant pressure facility, as disclosed in Korean Patent Publication No. 10-1992640 "Testing system for natural gas constant pressure facility" (registration date: 2019.06.19), natural gas is depressurized to a constant pressure a static pressure device that supplies gas to consumers; a feeder for first reducing the pressure of natural gas supplied to the static pressure machine to a pressure higher than the pressure of natural gas supplied from the static pressure machine to a gas demander; a pilot controlling the degree of opening/closing of the static pressure machine by supplying the second pressure-reduced natural gas to the static pressure device by the second pressure reduction in the feeder; and a nitrogen tank for storing nitrogen; a first nitrogen line connected so that the nitrogen stored in the nitrogen tank is supplied to the feeder; and a second nitrogen line connected so that the nitrogen stored in the nitrogen tank is supplied to the static pressure device; further including, during the test operation of the static pressure machine, performing the test operation using the nitrogen stored in the nitrogen tank, a natural gas constant pressure facility A commissioning system is provided.

As a prior art related to the existing natural gas static pressure machine, as disclosed in Korean Patent Publication No. 10-1048334 "Opening degree display device of natural gas static pressure machine" (registration date: 2011.07.05), a mounting plate mounted on the static pressure device housing and ; a valve opening degree transmitter mounted on one side of the mounting plate and having an actuator rod protruding through the mounting plate to the other side; and a rack & pinion mechanism that connects the indicator rod linked to the diaphragm inside the static pressure housing and the actuator rod of the valve opening transmitter to rotate the actuator rod according to the rising amount of the indicator rod.

Existing static pressure devices monitor the supply flow rate of city gas companies and power plants through a remote sensing system, and the desired pressure can be monitored through a transmitter to monitor the opening state.

The existing opening rate display device that displays the opening state of the static pressure device is installed in a link-type structure, so it has a structure in which a malfunction and an opening time cannot be accurately known.

The structure of the current open rate display device of the static pressure machine has a structure that indicates the open rate (Open/Close) according to the movement degree of the diaphragm installed in the main body of the constant pressure machine.

The link-type opening rate display device is connected to the diaphragm by a rod, so the opening rate (Open/Close) frequently changes depending on the gap between the rods, the tightening state of the bolts, and the position of the link, and there is a risk of gas leakage in the part connected to the diaphragm by a rod. has a

In addition, in the past, an opening degree indicator (potentiometer) indicating the degree of opening of the static pressure facility was used in the field to monitor the operation status of the static pressure facility. Therefore, the resistance value is detected by moving the static pressure device up and down, and the signal is converted and transmitted, and this is used for remote monitoring.

In the signal detection and transmission method described above, the resistance value reacts sensitively to minute up and down movements and external vibrations, resulting in a large transmission error rate. There is a risk of safety accidents if it leads to system malfunction.

Korean Patent Publication No. 10-1992640 "Testing system of natural gas static pressure facility" (Registration date: 2019.06.19) Korean Patent Publication No. 10-1048334 "Opening degree display device of natural gas static pressure device" (Registration date: 2011.07.05)

The present invention was devised to solve these problems in consideration of the above-mentioned problems, and its purpose is to indicate the differential pressure between the upper and lower chambers generated during the operation of the static pressure gauge from the differential pressure gauge so that the operator can accurately recognize it and signal output. An object of the present invention is to provide a device for displaying the opening degree of a static pressure device whose structure is improved so as to remotely monitor the opening degree of the static pressure in the field by transmitting it to the outside through a line.

The present invention for achieving the above object is a static pressure gauge opening rate display device having a differential pressure gauge that displays the differential pressure between the upper and lower chambers generated during the operation of the static pressure device divided into the upper and lower chambers based on the diaphragm, wherein the differential pressure gauge comprises: A medium-pressure gas inlet connected by a pipe to the upper chamber and the static pressure gas bleed, and a low-pressure gas inlet pipe-connected to the lower chamber and pipe-connected to the pre-regulator, so as to display the generation of differential pressure in the upper and lower chambers when the static pressure machine is operated characterized in that it is composed.

The differential pressure gauge further includes a signal output line for outputting the differential pressure to the outside when the differential pressure of the static pressure gauge is generated.

The present invention instructs the differential pressure of the upper and lower chambers generated during operation of the static pressure machine with a differential pressure gauge, thereby blocking errors caused by external factors so that the operator can recognize the correct opening rate of the static pressure machine, and, in addition, the signal output line By transmitting it to the outside through the system, it is possible to remotely monitor the opening degree of the static pressure in the field, which has a useful advantage of accurately identifying the operating state of the facility.

1 is a configuration diagram schematically showing the configuration of an opening degree display device of a static pressure device according to the present invention.

Hereinafter, the present invention will be described in more detail through the detailed description of the embodiments with reference to the drawings.

In describing the present invention, if it is determined that a detailed description of a related known technology or configuration may unnecessarily obscure the subject matter of the present invention, a detailed description thereof will be omitted. And the terms to be described later are terms defined in consideration of functions in the present invention, and may vary according to the intention or custom of the user. Therefore, the definition should be made based on the content throughout this specification. In addition, 'including' a certain component means that other components may be further included, rather than excluding other components, unless otherwise stated.

The opening degree display device of the static pressure device according to the present invention will be described with reference to FIG. 1 , the upper and lower chambers ( A static pressure opening degree display device having a differential pressure gauge 100 for displaying the differential pressure of 240 and 230, wherein the differential pressure gauge 100 includes a medium pressure gas inlet 130 connected to the upper chamber 240 and the static pressure gas bleed through a pipe, and the lower portion By having a low-pressure gas inlet 120 that is pipe-connected to the chamber 230 and pipe-connected to the pre-regulator 320, it is configured to display the generation of differential pressure in the upper and lower chambers 240 and 230 when the static pressure device 210 is operated. .

With respect to the static pressure device 210 , the left (front end) gas pressure is referred to as primary pressure, and the right (rear) gas pressure is referred to as secondary pressure.

Primary pressure is applied to the lower chamber 230 of the static pressure device 210 , and secondary pressure is applied to the upper chamber 240 .

Referring to FIG. 1 , the primary pressure gas pipe is connected to one side of the pilot 310 to transmit the jacket pressure, and the preregulator 320 is piped to the other side of the pilot 310 , and one side of the pilot 310 . A pipe is connected so that the gas sensing pressure of the secondary pressure acts to the inside between the and the other side.

The differential pressure gauge 100 has a low-pressure gas inlet 120 and a medium-pressure gas inlet 130 respectively pipe-connected to the manifold, and a signal output line 140 for outputting it to the outside when the differential pressure is generated by the static pressure gauge 210 is provided.

The signal output line 140 may serve as a power supply line for supplying power to the differential pressure gauge 100 side.

If the differential pressure between the primary side jacket pressure and the secondary side sensing pressure is greater than the set value of the pilot 310, the pilot 310 does not operate, and the secondary side sensing pressure flows into the static pressure gas bleed 250 and enters the static pressure upper chamber ( 240) and the lower chamber 230 have the same pressure value.

Therefore, the pressure difference between the medium pressure and the low pressure supplied through the medium pressure gas inlet 130 and the low pressure gas inlet 120 of the differential pressure gauge 100 is 0 Kpa, and the differential pressure gauge 100 indicates 0%.

When the secondary-side sensing pressure is less than the set value of the pilot 310 and the pre-regulator 320 , the pilot 310 operates, and a gas flow occurs in the medium-pressure gas inlet 130 of the differential pressure gauge 100 , and accordingly As gas flows into the lower chamber 230 of the static pressure regulator 210 , the diaphragm 220 is lifted to operate the static pressure device 210 .

As the diaphragm 220 is lifted during operation of the static pressure device 210, the low pressure gas of the upper chamber 240 flows to the low pressure gas inlet 120 of the differential pressure gauge 100 through the static pressure gas bleed 250. .

When the static pressure device 210 is operating, differential pressure is generated in the upper and lower chambers 240 and 230 , and it is possible to remotely monitor the pressure through the differential pressure gauge 100 for operation monitoring and remote monitoring with the signal output line 140 .

0% is set to 0Kpa, 100% is set to 500Kpa for the static pressure gauge opening of the differential pressure gauge 100

That is, the static pressure device 210 does not generate a difference between the jacket pressure on one side and the sensing pressure on the other side of the pilot 310 when the operation is stopped, whereas the upper and lower chambers ( 240,230) can be indicated in the field.

Therefore, the present invention, unlike the existing opening rate display device, by instructing the differential pressure gauge 100 to indicate the differential pressure between the upper and lower chambers 240 and 230 generated during the operation of the static pressure device 210, to block errors caused by external factors. In addition to allowing the operator to recognize the correct opening rate of the static pressure device, it is transmitted to the outside through the signal output line 140, so that it is possible to remotely monitor the opening rate of the static pressure in the field, so that the equipment operation status can be accurately identified. has useful advantages.

100: differential pressure gauge 110: manifold
120: low pressure gas inlet 130: medium pressure gas inlet
140: signal output line 210: constant pressure
220: diaphragm 230: lower chamber
240: upper chamber 250: constant pressure gas bleed
310: pilot 320: pre-regulator

Claims (2)

A static pressure opening degree display device having a differential pressure gauge 100 that displays the differential pressure between the upper and lower chambers 240 and 230 generated during the operation of the static pressure device 210 divided into upper and lower chambers 240 and 230 based on the diaphragm 220 . as,
The differential pressure gauge 100 includes a medium pressure gas inlet 130 connected to the upper chamber 240 and the static pressure gas bleed 250 by piping;
and a low pressure gas inlet 120 connected to the lower chamber 230 and piped to the pre-regulator 320,
It is configured to display the generation of differential pressure in the upper and lower chambers 240 and 230 when the static pressure device 210 is operated,
The differential pressure gauge 100 further includes a signal output line 140 for outputting the differential pressure to the outside when the differential pressure of the static pressure gauge 210 occurs,
The signal output line 140 has a function of a power supply line for supplying power to the differential pressure gauge 100 side,
If the differential pressure between the primary side jacket pressure and the secondary side sensing pressure is greater than the set value of the pilot 310, the pilot 310 does not operate, and the secondary side sensing pressure flows into the static pressure gas bleed 250 and the static pressure upper chamber ( 240) and the pressure value of the lower chamber 230 become the same, and the differential pressure gauge 100 indicates 0%,
When the secondary-side sensing pressure is less than the set value of the pilot 310 and the pre-regulator 320 , the pilot 310 operates, and a gas flow occurs in the medium-pressure gas inlet 130 of the differential pressure gauge 100 , and accordingly As gas flows into the lower chamber 230 of the static pressure device 210, the diaphragm 220 is lifted to operate the static pressure device 210, thereby generating a differential pressure in the upper and lower chambers 240 and 230. Through (100), remote monitoring is possible with on-site instruction and signal output line (140),
Unlike the existing open rate display device, the differential pressure gauge 100 indicates the differential pressure of the upper and lower chambers 240 and 230 generated during the operation of the static pressure device 210, thereby blocking errors caused by external factors and providing an accurate pressure device to the operator. In addition to making it possible to recognize the opening rate of the static pressure opening rate display device, characterized in that it is possible to monitor the opening rate of the static pressure in the field remotely by transmitting it to the outside through the signal output line (140). delete

Images