KR101403614B1 - Gas and liquid seperating system - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a gas-liquid separating system, and more particularly, to a gas-liquid separating system for separating gas blow-by from a suction gas scrubber according to a gas pressure on an inlet side of a compressor, The present invention relates to a gas-liquid separating system capable of avoiding unnecessary application of a low-cost material such as stainless steel or titanium, and at the same time, preventing material changes in equipment, piping,
According to the present invention, there is provided a vacuum cleaner comprising: a suction scrubber for separating an incoming fluid into a gas and a liquid; A compressor installed in a gas transfer line through which gas separated from the suction scrubber is discharged; A liquid shutoff valve installed in a liquid discharge line through which the liquid separated from the suction scrubber is discharged; A pressure sensor for measuring a pressure of gas flowing into the compressor and outputting a sensing signal; A controller that receives the sensing signal output from the pressure sensor and closes the liquid shutoff valve when the pressure of the gas flowing into the compressor reaches a predetermined first pressure value; Liquid separation system.

Description

[0001] GAS AND LIQUID SEPERATING SYSTEM [0002]

The present invention relates to a gas-liquid separating system for separating a gas and a liquid, and more particularly, to a gas-liquid separating system for separating a gas and a liquid, which prevents a low temperature phenomenon due to gas blow- Liquid separation system configured to avoid application of a material.

Generally, a suction scrubber is a device for filtering out liquid substances in a fluid. When a gas such as an evaporation gas generated from an LNG tank is compressed by a compressor, the suction scrubber is installed at the front end of the compressor, Can be used to remove liquid components contained in the incoming gas.

Such a suction scrubber separates a liquid from a gas by various methods. For example, coalescing phenomenon is used to filter out fine liquid components contained in the gas, and the filtered liquid components are agglomerated to increase the density So that the condensed liquid is collected in the lower part and discharged to the outside through the discharge pipe.

However, in such a suction scrubber, when a blow-by gas is blown through a nozzle for discharging a liquid, an excessive low temperature phenomenon due to a pressure drop occurs in the downstream system. As a result, , Valves, piping, and the like must be designed and manufactured with a low-temperature-resistant material such as stainless steel or titanium.

Published Patent Publication No. 10-2009-0095223 (published on September 9, 2009)

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems of the prior art, and it is an object of the present invention to provide a suction scrubber which is capable of preventing blow-by of gas in a nozzle for discharging liquid of a suction scrubber, To avoid the application of the < / RTI >

According to an aspect of the present invention, there is provided a vacuum cleaner comprising: a suction scrubber for separating an inflowing fluid into a gas and a liquid; A compressor installed in a gas transfer line through which gas separated from the suction scrubber is discharged; A liquid shutoff valve installed in a liquid discharge line through which the liquid separated from the suction scrubber is discharged; A pressure sensor for measuring a pressure of gas flowing into the compressor and outputting a sensing signal; A controller that receives the sensing signal output from the pressure sensor and closes the liquid shutoff valve when the pressure of the gas flowing into the compressor reaches a predetermined first pressure value; Liquid separation system.

Preferably, the first pressure value is a pressure value that causes a minimum temperature at which the material of the equipment or the piping can withstand by blow-by generated in the liquid discharge line.

And the controller closes the liquid shutoff valve while keeping the operation of the compressor.

The suction scrubber preferably includes a level sensor for detecting the level of the separated liquid.

The suction scrubber includes: an exhaust line connected to an upper portion of the suction scrubber for exhausting gas in an emergency; A safety valve for opening the exhaust line for safety when the pressure in the suction scrubber reaches a predetermined pressure; .

Wherein the gas transfer line comprises: a bypass line connected to bypass the compressor; An on-off valve installed to open and close the bypass line; .

The controller preferably controls to stop the operation of the system connected to the compressor and the compressor when the pressure of the gas flowing into the compressor reaches a second pressure value lower than the first pressure value.

According to another aspect of the present invention, there is provided a suction scrubber for measuring a pressure of a gas introduced into a compressor through a suction scrubber, wherein the suction scrubber is operated to maintain the operation of the compressor when a pressure value of the measured gas reaches a first pressure value, Wherein the first pressure value is a minimum temperature that the material of the equipment downstream of the suction scrubber can withstand when a blow-by of gas through the liquid discharge nozzle of the suction scrubber occurs A gas-liquid separation system is provided.

According to the present invention, gas blow-by on the side where the liquid is discharged from the suction scrubber is blocked in accordance with the gas pressure on the inflow side of the compressor, whereby the low-temperature material such as stainless steel, titanium or the like And at the same time, it is possible to prevent the material of equipment, piping, and the like from being changed according to the analysis result.

1 is a configuration diagram illustrating a gas-liquid separation system according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In addition, the following examples can be modified in various forms, and the scope of the present invention is not limited to the following examples.

1 is a configuration diagram illustrating a gas-liquid separation system according to an embodiment of the present invention.

1, a gas-liquid separation system 100 according to an embodiment of the present invention includes a suction scrubber 110 for separating an inflow fluid into a gas component and a liquid component, a suction scrubber 110 A pressure sensor 140 for measuring the pressure of a gas component, that is, a gas, which is separated from the compressor 120 and outputs the gas component as a sensing signal, a controller (controller) 140 receiving the sensing signal of the pressure sensor 140, 150 < / RTI >

The suction scrubber 110 removes the liquid component from the incoming gas, thereby allowing the liquid to discharge the removed gas. The suction scrubber 110 may have various systems and structures for separation of gas and liquid and removal of liquid. For example, the suction scrubber 110 may filter the fine liquid substances contained in the gas using condensation phenomenon, The liquid may be collected and discharged through the lower liquid discharge nozzle 111. Here, the gas may include all gases that may cause evaporation or natural gas, as well as equipment, pipes, etc. in the downstream system that may cause a low temperature phenomenon due to pressure drop.

The suction scrubber 110 may be provided with a level sensor 112 that senses the level of the liquid collected and collected from the gas so that the level of the liquid can be maintained within a predetermined range. The controller or the operator can adjust the discharge of the liquid from the suction scrubber 110 so that the liquid level in the suction scrubber 110 can be maintained within a predetermined range by utilizing the information sensed by the level sensor 112, The flow of gas to the scrubber 110 can be controlled, and various other methods can be applied.

A gas transfer line 160 for supplying gas separated from the liquid to the compressor 120 and an exhaust line 113 for exhausting gas in an emergency can be connected to the upper portion of the suction scrubber 110. A pressure safety valve (PSA) 114 may be installed in the exhaust line 113 to open the exhaust line 113 for safety when the pressure in the suction scrubber 110 reaches a predetermined pressure.

At the lower end of the suction scrubber 110, a liquid discharge line 131 for providing a path for discharging liquid through the liquid discharge nozzle 111 and a liquid shutoff valve 130 is connected.

The compressor 120 is installed on a gas transfer line 160 for transferring the gas discharged from the suction scrubber 110 in order to supply gas from the suction scrubber 110, After the removal process, the gas introduced can be compressed using the driving force of the motor 121.

A bypass line 161 may be connected to the gas transfer line 160 to bypass the compressor 120. The bypass line 161 may be provided with an on-off valve 162 for opening and closing the bypass of the gas to the compressor 120.

The liquid shutoff valve 130 may be a control valve installed in a discharge line 131 through which the liquid is discharged from the suction scrubber 110 and may be operated by a control signal of the controller 150. For example, And a valve that operates according to a hydraulic pressure or an electrical signal.

The pressure sensor 140 measures the pressure of the gas flowing into the compressor 120 and outputs the measured pressure as a sensing signal. The pressure sensor 140 detects the pressure of the gas flowing in the compressor 120 from the gas transfer line 160 through which the gas discharged from the suction scrubber 110 is transferred, As shown in FIG.

The controller 150 is configured to receive the sensing signal output from the pressure sensor 140 and to maintain the operation of the compressor 120 when the pressure of the gas flowing into the compressor 120 reaches a predetermined first pressure value The liquid shutoff valve 130 is closed.

Here, the first pressure value is a pressure value at which blow-by through the liquid discharge nozzle 111 of the suction scrubber 110 may occur. If blow-by through the liquid discharge nozzle 111, a cryogenic phenomenon due to a pressure drop may occur in equipment or piping located downstream of the suction scrubber 110, which is undesirable.

The first pressure value is selected in the downstream equipment or piping due to the occurrence of excessive low temperature due to the blow-by of the gas through the liquid discharge nozzle 111 of the suction scrubber 110 Can be obtained by performing calculations to prevent problems with the material, ie, the pressure that causes the lowest temperature that can be tolerated by such equipment or piping material can be obtained by the Thomson effect, Can be obtained.

When the pressure of the gas flowing into the compressor 120 exceeds the first pressure value and reaches a predetermined second pressure value, the controller 150 controls the system connected to the compressor 120, for example, The compressor 120 and the device at the rear end of the compressor 120 may be controlled to stop operation. Here, the second pressure value may have a value smaller than the first pressure value.

The pressure sensor 140 may control the system 150 connected to the compressor 120 when the pressure of the gas flowing into the compressor 120 reaches the second pressure value instead of the control of the controller 150 with respect to the second pressure value. And a pressure switch for stopping the operation of the switch.

The operation of the gas-liquid separation system according to the present invention will now be described.

The controller 150 determines whether the gas pressure at the front end of the compressor 120 measured by the pressure sensor 140 reaches a first set value, for example, a minimum temperature at which the material of the piping or the equipment located at the rear end of the suction scrubber 110 can withstand The liquid shutoff valve 130 for shutting off the liquid discharged from the suction scrubber 110 is closed while the normal operation of the compressor 120 is maintained. Thus, blow-by of the gas through the liquid discharge nozzle 111 of the suction scrubber 110 is originally blocked.

Accordingly, it is possible to avoid unnecessary application of expensive low-temperature materials such as stainless steel or titanium to the above-mentioned equipment and piping, and at the same time, it is possible to prevent the material change of equipment and piping according to the analysis result.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit and scope of the invention will be.

110: Suction scrubber 111: Liquid discharge nozzle
112: Level sensor 113: Exhaust line
114: Safety valve 120: Compressor
121: motor 130: liquid shutoff valve
131: liquid discharge line 140: pressure sensor
150: controller 160: gas transfer line
161: bypass line 162: opening / closing valve

Claims (8)

A suction scrubber for separating the inflowing fluid into a gas and a liquid;
A compressor installed in a gas transfer line through which gas separated from the suction scrubber is discharged;
A liquid shutoff valve installed in a liquid discharge line through which the liquid separated from the suction scrubber is discharged;
A pressure sensor for measuring a pressure of gas flowing into the compressor and outputting a sensing signal;
A controller that receives the sensing signal output from the pressure sensor and closes the liquid shutoff valve when the pressure of the gas flowing into the compressor reaches a predetermined first pressure value;
/ RTI > 2. The gas-liquid separation system according to claim 1, wherein the first pressure value is a pressure value that causes a minimum temperature to withstand the material of the equipment or the piping by blow-by generated in the liquid discharge line. The gas-liquid separation system according to claim 1, wherein the controller closes the liquid shut-off valve in a state in which operation of the compressor is maintained. The gas-liquid separation system according to claim 1, wherein the suction scrubber includes a level sensor for detecting the level of the separated liquid. The suction scrubber according to claim 1,
An exhaust line connected to the upper portion to exhaust gas in an emergency;
A safety valve for opening the exhaust line for safety when the pressure in the suction scrubber reaches a predetermined pressure;
/ RTI > The gas delivery system according to claim 1,
A bypass line connected to bypass the compressor;
An on-off valve installed to open and close the bypass line;
/ RTI > The gas-liquid separation system according to claim 1, wherein the controller controls to stop the operation of the compressor when the pressure of the gas flowing into the compressor reaches a second pressure value lower than the first pressure value. The pressure of the gas flowing into the compressor through the suction scrubber is measured and the discharge of the liquid from the suction scrubber is blocked while the operation of the compressor is maintained when the pressure value of the measured gas reaches the first pressure value ,
Wherein the first pressure value is a pressure value that causes a minimum temperature that the material of the equipment downstream of the suction scrubber can withstand when a blow-by of gas through the liquid discharge nozzle of the suction scrubber occurs.

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