KR101854233B1 - Compressor system - Google Patents

Abstract

The compressor system according to the present invention comprises a first point provided between the first shutdown valve and the first compressor, a second point provided between the first compressor and the intermediate valve, and a second point provided between the intermediate valve and the second compressor And a fourth point provided between the second compressor and the second shutdown valve, the compressor system comprising: a first bypass line connecting between a first point and a second point; A first anti-surge valve provided on the first bypass line; A second bypass line connecting between a third point and a fourth point; A second anti-surge valve provided on the second bypass line; A third bypass line connecting between the first point and the fourth point; And a mixed-balance valve provided on the third bypass line, wherein the first anti-surge valve, the second anti-surge valve, and the mixed-balance valve are opened and closed together to control surge phenomenon in an emergency .

Description

[0001] COMPRESSOR SYSTEM [0002]

The present invention relates to a compressor system, and more particularly to a compressor system including a compressor and an anti-surge valve (ASV).

A surge is a phenomenon in which the fluid flow of a compressor instantaneously reverses. When a surge occurs, the temperature of the fluid to be compressed rises sharply. In addition, it causes problems such as stress, noise and vibration inside the compressor. Such a problem may eventually cause damage to the rotor. To prevent this, methods for preventing and reducing the surge phenomenon have been continuously invented, and Patent Document 10 (Japanese Published Patent Application No. 2001-0003912 Discloses one of the methods.

In a compressor system for preventing surge, a re-circulation system using a circulation path connecting the front and rear of the compressor is used. In this compressor system, when an emergency (ESD) occurs, a shutdown valve (SDV) installed before and after the compression system is closed, and an anti-surge valve (Anti -surge valve is opened and the pressure of the front and rear ends of the compressor system is balanced so that the emergency situation is canceled.

However, such a compressor system has some problems. In ESD, it takes a long time for the pressure before and after the compressor system to reach the equilibrium pressure (SOP) and thus the length of the flare tower is increased. In particular, this problem is highlighted in a multi-stage compression system.

Korean Patent Publication No. 10-2012-0003912

SUMMARY OF THE INVENTION It is an object of the present invention to provide a compressor system in which the pressure before and after a compressor system can be reached within an equilibrium pressure (SOP) in a short time.

According to an aspect of the present invention, there is provided a compressor comprising a first point provided between a first shutdown valve and a first compressor, a second point provided between a first compressor and an intermediate valve, and a second point provided between the intermediate valve and the second compressor And a fourth point provided between the second compressor and the second shutdown valve, the compressor system comprising: a first bypass line connecting between a first point and a second point; A second anti-surge valve provided on the pass line, a second bypass line connecting between the third point and the fourth point, a second anti-surge valve provided on the second bypass line, A third bypass line connecting the fourth anti-surge valve and the fourth point, and a mixed-balance valve provided on the third bypass line, wherein the first anti-surge valve, the second anti- , At least one of the mixed equilibrium valves To control the woman surges can be provided with a compressor system.

The first compressor and the second compressor may each include a first scrubber disposed at an inlet side and a first heat exchanger disposed at an outlet side of the first compressor and the second compressor.

The first compressor and the second compressor may each include a first heat exchanger at an inlet side and a first scrubber at an outlet side.

A first flare line connected to the flare tower may be provided at the second point, and a first blow-down valve may be disposed on the first flare line.

According to another aspect of the present invention, there is provided a compressor comprising a first point provided between a first shutdown valve and a first compressor, a second point provided between a first compressor and an intermediate valve, and a second point provided between the intermediate valve and the second compressor And a fourth point provided between the second compressor and the second shutdown valve, the compressor system comprising: a first bypass line connecting between a first point and a second point; A second anti-surge valve provided on the pass line, a second bypass line connecting between the third point and the fourth point, a second anti-surge valve provided on the second bypass line, A third bypass line connecting the third anti-surge valve and the third point, and a mixed equilibrium valve provided on the third bypass line, wherein the first anti-surge valve, the second anti- And at least one of the mixed equilibrium valves is used To control the woman surges can be provided with a compressor system.

In the compressor system according to the present invention, the third bypass line and the mixed equilibrium valve may be provided to lower the combined settle out pressure than the settle out pressure of the existing high pressure side. This leads to a reduction in the peak blowdown discharge, which reduces the size of the blowdown line and reduces the size of the flare head.

In addition, the height of the flare stack can be reduced by reducing the peak blowdown discharge at each point.

In addition, if the third bypass line and the mixed equilibrium valve are provided and the low pressure / high pressure (LP / HP) side is mixed and discharged, there is an advantage that the first flare line need not be installed separately.

In addition, by installing a mixed equilibrium valve, the pressure of the high pressure part / the low pressure part can be made equilibrium in a short time.

1 is a configuration diagram of a conventional compressor system.
2 is a configuration diagram of a compressor system according to the first embodiment of the present invention.
3 is a configuration diagram of a compressor system according to a second embodiment of the present invention.
4 is a configuration diagram of a compressor system according to a third embodiment of the present invention.
5 is a configuration diagram of a compressor system according to a fourth embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. The embodiments described below are provided by way of example so that those skilled in the art will be able to fully understand the spirit of the present invention. The present invention is not limited to the embodiments described below and may be embodied in other forms. In order to clearly explain the present invention, parts not related to the description are omitted from the drawings, and the width, length, thickness, etc. of the components may be exaggerated for convenience. Like reference numerals designate like elements throughout the specification.

FIG. 1 shows a block diagram of a conventional compressor system. Referring to FIG. 1, a compressor system generally used will be briefly described.

Although a multi-stage compressor system is shown in FIG. 1, a general compressor system will be described first before describing it. In the compressor system, when an emergency (ESD) occurs, the shutdown valve (SDV) installed before and after the compression system is closed and the anti-surge valve (Anti -surge valve is opened, so that the pressure of the front end and the rear end of the compression system are balanced. At this time, the equilibrium pressure is called the settled out pressure (SOP).

The reason why the pressure before and after the compressor system is brought to the equilibrium pressure (SOP) is that one of the factors determining the height of the flare tower is the flow rate of the gas discharged at the time of blowdown, If the pressure on one side of the system is excessively high, the flow rate will increase accordingly.

After the pressure equilibrates, the blowdown valve opens and the hydrocarbon passing through it is sent to the flare section to flare. At this time, normally, the blowdown valve starts to open after 30 seconds after the ESD signal is generated. This allows the compressor system to operate reliably.

However, in a multi-stage compression system as shown in FIG. 1, it takes a long time for the pressure before and after the compressor system to reach the equilibrium pressure (SOP) in an emergency situation (ESD) Therefore, there is a problem that the length of the flare tower is increased.

The low pressure portion LP and the high pressure portion HP are formed depending on the positions where the compressors C1 and C2 are installed and the blowdown line and the flare head A large peak blowdown discharge is generated in the exhaust gas.

Specifically, in a single stage multi-stage compression system, when a compressor is tripped in an emergency, a small amount of fluid flows from the high pressure portion HP to the low pressure portion LP through the shaft when the compressor is stopped The pressure becomes equilibrium. The time required for the high pressure part (HP) and the low pressure part (LP) to reach the equilibrium pressure takes about 2 minutes or more. At this time, if the hydrocarbon is discharged from the high pressure state to the high pressure flare (HP flare) before the high pressure part (HP) and the low pressure part (LP) reach the settle out pressure, In the end, the height of the flare tower must be high.

Accordingly, the pressure of the high-pressure / low-pressure portion is equilibrated in a short time (30 seconds), thereby reducing the peak blowdown discharge, thereby reducing the size of the blowdown line and reducing the size of the flare head Reducing the size, reducing the settle out pressure of the high pressure part (HP) side and reducing the peak blowdown discharge of the blowdown line connected thereto to reduce the height of the flare stack There is a need.

2 is a configuration diagram of a compressor system according to the first embodiment of the present invention. Hereinafter, a compressor system according to a first embodiment of the present invention will be described with reference to FIG.

The compressor system according to the first embodiment of the present invention includes a first shutdown valve 110, a first check valve 120, a first scrubber 130, a first compressor 140, a first heat exchanger 150 The first anti-surge valve 160, the first blowdown valve 170, the intermediate valve 180, the second scrubber 230, the second compressor 240, the second heat exchanger 250, the second anti- A third shut-off valve 290, and a mixed equilibrium valve 300. The anti-surge valve 260, the second blowdown valve 270, the third check valve 280, the second shutdown valve 290, Hereinafter, each of these configurations will be described.

The first point S1 shown in the drawing refers to a pipe disposed between the first check valve 120 and the first scrubber 130 in the figure and the second point S2 is a pipe disposed between the first heat exchanger 150 and the second scrubber 130. [ The third point S3 is a pipe disposed between the intermediate valve 180 and the second scrubber 230 and the fourth point S4 is a pipe disposed between the second heat exchanger 250 and the third check valve 280, respectively.

The first bypass line B1 is connected to the pipe line connecting the first point S1 and the second point S2 and the second bypass line B2 is connected to the third point S3 and the fourth point S4 and the third bypass line B3 is a line connecting the first point S1 and the fourth point S4.

The first flare line F1 is branched at the second point S2 to be connected to the flare and the second flare line F2 is branched at the fourth point S4 to be connected to the flare. do.

First, the first shutdown valve 110 may control the opening and closing of the incoming gas. This first shutdown valve 110 may be located between the input gas and the first point S1. Also, the first shutdown valve 110 can regulate the flow rate through it. At this time, the first shutdown valve 110 may be, for example, a throttling valve.

Next, the first check valve 120 may be a different type of double check valve opened only in the direction in which the fluid is discharged. At this time, since the first check valve 120 is provided as a double check valve of different type, the reverse flow of the fluid due to abnormal operation of the fluid supply device is blocked, and the inside of the body is coated with a corrosion- It is possible to prevent the contamination of the piping and the clogging of the piping. In addition, since the first check valve 120 is provided as a double check valve of different type, a highly efficient and practically used backflow prevention device can be provided. The first check valve 120 may serve to open the fluid when the pressure of the fluid flowing through the first check valve 120 is higher than the first pressure.

Next, the first scrubber 130 may function to purify the gas flowing into the first scrubber 130. This is a method for collecting solid or liquid particles suspended in a gas by using a liquid. The principle is to disperse the liquid into a gas containing dust, , Adhesion of particles due to humidity increase, prevention of re-scattering of collected particles due to a liquid film, increase in particle diameter due to condensation, or the like.

Next, the first compressor 140 may include an inlet through which the fluid enters and an outlet through which the fluid enters, thereby compressing the gas introduced thereinto. At this time, the first compressor 140 may be of a rotary type that compresses the gas by a rotor. The output of the first compressor 140 is not particularly limited, but may be 100 kPa or more, but is not limited thereto.

Next, the first heat exchanger 150 may serve to lower the temperature of the fluid passing through it. The temperature of the gas passing therethrough is appropriately adjusted. In the first scrubber 130, the first compressor 140 and the first heat exchanger 150, the first scrubber 130 is disposed at the inlet side of the first compressor 140, And the first heat exchanger 150 may be provided at the outlet side. This means that the first compressor 140 compresses the purified gas and then adjusts the temperature of the compressed gas.

The first anti-surge valve 160 may be provided on a line connecting between the first point S1 and the second point S2 to suppress the surge phenomenon. At this time, when the first anti-surge valve 160 is opened, the pressure difference between the first point S1 and the second point S2 can be reduced. The first anti-surge valve 160 may be opened to suppress the surge when an emergency situation (ESD) occurs.

Further, the first anti-surge valve 160 can be opened only in one direction. The one direction may be a direction extending from the second point S2 to the first point S1.

The first blowdown valve 170 may be provided in the first flare line F1 and may serve to determine whether or not gas passing therethrough is sent to the flare tower. The first anti-surge valve 160 is opened and the pressure at the first point S1 and the second point S2 becomes equal to each other. After that, the first blowdown valve 160 170 is opened and the hydrocarbon flowing through it is sent to the flare part. At this time, the blowdown valve may start to open after 30 seconds after the ESD signal is generated.

On the other hand, the first blowdown valve 170 may be omitted along with the first flare line F1. That is, the first blowdown valve 170 and the first flare line F1 are not essential elements because the third bypass line B3 and the mixed-balance valve 300 are provided. When the third bypass line B3 and the mixed ball valve 300 are provided and the difference in pressure between the respective points S1, S2, S3, and S4 becomes small, the first flare line F1 and the second flare line 300, This is because the compressor system can be stably operated only by the second flare line F2 without setting the line F2 separately. This has the effect of reducing additional capital expenditures and operating costs.

Next, the intermediate valve 180 may be a different type of double check valve opened only in the direction in which the fluid is discharged. At this time, since the intermediate valve 180 is provided as a double check valve of a different type, the back flow of the fluid due to abnormal operation of the fluid supply device is completely blocked, and the inside of the body is coated with a corrosion- It is possible to prevent the contamination of the piping and the clogging of the piping. The intermediate valve 180 may be opened when the pressure of the fluid flowing through the intermediate valve 180 is higher than a predetermined pressure. The intermediate valve 180 may be opened above the second pressure, unlike the first check valve 120 is opened above the first pressure. This second pressure may be greater than the first pressure.

Next, the second scrubber 230 may serve to purify the gas flowing into the second scrubber 230. This is a method for collecting solid or liquid particles suspended in a gas by using a liquid. The principle is to disperse the liquid into a gas containing dust, , Adhesion of particles due to humidity increase, prevention of re-scattering of collected particles due to a liquid film, increase in particle diameter due to condensation, or the like.

The second compressor 240 includes an inlet through which the fluid enters and an outlet through which the fluid enters, thereby compressing the gas introduced into the second compressor 240. At this time, the second compressor 240 may be of a rotary type that compresses the gas by a rotor. The output of the second compressor 240 is not particularly limited, but may be 100 kPa or more, but is not limited thereto.

The second heat exchanger 250 may serve to lower the temperature of the fluid passing through it. The temperature of the gas passing therethrough is appropriately adjusted.

The second anti-surge valve 260 may be provided on the second bypass line B2 connecting between the third point S3 and the fourth point S4 to suppress the surge phenomenon. At this time, when the second anti-surge valve 260 is opened, the pressure difference between the third point S3 and the fourth point S4 can be reduced.

Next, the second blowdown valve 270 may be provided in the second flare line F2 to determine whether or not the gas passing therethrough is sent to the flare tower. The second anti-surge valve 260 is opened, and the pressure at the third point S3 and the fourth point S4 becomes equal to each other. Thereafter, the first blowdown valve 270 is opened and the hydrocarbon flowing through it is sent to the flare part. At this time, the blowdown valve may start to open after 30 seconds after the ESD signal is generated.

The third check valve 280 may be a different type of double check valve opened only in the direction in which the fluid is discharged. At this time, the third check valve 280 is provided as a double check valve of a different type, thereby completely preventing the reverse flow of the fluid due to abnormal operation of the fluid supply device, and coating the inside of the body with a corrosion- It is possible to prevent contamination of piping and blockage of piping due to residue. The third check valve 280 may serve to open the fluid if the pressure of the fluid flowing through the third check valve 280 is higher than a specific pressure. Also, the third check valve 280 may be opened above the third pressure, unlike the intermediate valve 180 is opened above the second pressure. The third pressure may be greater than the second pressure.

Next, the second shutdown valve 290 can control the opening and closing of the discharged gas. This second shutdown valve 290 may be located after the fourth point S4. The second shutdown valve 290 can also control the flow rate through it. At this time, the second shutdown valve 290 may be, for example, a throttling valve. And the second shutdown valve 290 can be opened when the flow rate of the second bypass line B2 increases. That is, when a surge occurs, the second shutdown valve 290 can be opened to relieve the surge.

The mixed equilibrium valve 300 may be provided on the third bypass line B3 and may serve to equilibrate the pressures of the first point S1 and the fourth point S4. The mixed-balance valve 300 may be opened when an emergency situation (ESD) occurs, like the anti-surge valves 160 and 260.

The mixed anti-surge valve 300, the first anti-surge valve 160 and the second anti-surge valve 260 are opened or closed together when an emergency occurs, so that the pressure between the respective points S1, S2, S3, You can quickly reduce your car. At this time, the mixed equilibrium valve 300, the first anti-surge valve 160, and the second anti-surge valve 260 may be opened or closed simultaneously or separately. For example, a pressure signal is received from a pressure sensor provided at each of the points S1, S2, S3, and S4, and the mixed balance valve 300 and the first anti-surge valve 160 And the second anti-surge valve 260 are individually opened and closed. When a surge phenomenon occurs between the third point S3 and the fourth point S4, only the second anti-surge valve 260 is opened, and the remaining mixed balance valve 300 and the first anti- Can be maintained in a closed state.

In this case, in the compressor system according to the first embodiment of the present invention, a control unit (not shown) for opening and closing the mixing balanced valve 300, the first anti-surge valve 160 and the second anti- Hour) may be separately provided, but the present invention is not limited thereto.

The configuration of the compressor system according to the first embodiment of the present invention has been described above. The following describes how this compressor system works.

First, in the compressor system according to the first embodiment of the present invention, the shutdown valves 110 and 290 installed at the front and rear ends of the compression system are closed and the anti-surge valves 160 and 260 are closed when the emergency system (ESD, Emergency) And the pressure between the first point S1 and the second point S2 and the pressure between the third point S3 and the fourth point S4 are balanced.

Next, the mixing balance valve 300 provided on the third bypass line B3 connecting the first point S1 and the fourth point S4 is opened and the first point S1 and the fourth point S4 The pressure of the first point S1 and the second point S2, the pressure of the third point S3 and the pressure of the fourth point S4 all have the same mixed equilibrium pressure.

The first blowdown valve 170 or the second blowdown valve 270 is then opened to flare the internal hydrocarbon of the compression system. At this time, the first blowdown valve 170 or the second blowdown valve 270 may be opened after 30 seconds after the ESD signal is generated. That is, the first and second points S2 and S3 and the fourth point S3 and the third point S3 are connected to each other in a short period of time through the third bypass line B3 and the mixed balance valve 300, (S4) to the equilibrium.

3 is a configuration diagram of a compressor system according to a second embodiment of the present invention. The second embodiment of the present invention differs from the first embodiment in that the heat exchangers 150 and 250 and the scrubbers 130 and 230 are installed in order at the inlet side of the compressors 140 and 240, respectively.

In the first embodiment, the installation positions of the heat exchangers 150 and 250 and the scrubbers 130 and 230 are different from each other. The heat exchanger and the check valve may be additionally provided according to a specific design method and implementation direction.

4 is a configuration diagram of a compressor system according to a third embodiment of the present invention.

In contrast to the first embodiment, the fourth embodiment differs from the first embodiment in that the fourth bypass line B4 is provided between the second point S2 and the third point S3. In addition, the mixed-balance valve 400 may also be mounted on the fourth bypass line B4.

In this third embodiment, unlike the first embodiment, the fourth bypass line B4 is relatively short so as to connect the second point S2 and the third point S3, Pressure equilibrium can be established between points.

At this time, the first anti-surge valve 160 and the second anti-surge valve 260 are opened in the emergency situation (ESD) and the first point S1, the second point S2, the third point S3, The pressures at the four points S4 are respectively balanced and then the mixing balance valve 400 is opened to adjust the pressure at each point. Or the mixed balance valve 400 and the first anti-surge valve 160 and the second anti-surge valve 260 may be opened at the same time, which is not limited to the designer's option.

5 is a configuration diagram of a compressor system according to a fourth embodiment of the present invention. The fourth embodiment of the present invention differs from the third embodiment in that the heat exchangers 150 and 250 and the scrubbers 130 and 230 are installed in order at the inlet side of the compressors 140 and 240, respectively.

In the first embodiment, the installation positions of the heat exchangers 150 and 250 and the scrubbers 130 and 230 are different from each other. The heat exchanger and the check valve may be additionally provided according to a specific design method and implementation direction.

As a result, in the compressor system according to the present invention, the third bypass line B3 and the mixed-balance valve 300 are provided to set the combined settle-out pressure to the balance pressure of the existing high- settle out pressure. This leads to a reduction of the peak blowdown discharge, which reduces the size of the blowdown line and reduces the size of the flare head.

In addition, the height of the flare stack can be reduced by reducing the peak blowdown discharge at each point.

When the third bypass line B3 and the mixed balance valve 300 are provided and the low pressure / high pressure LP / HP side is combined and discharged, the first flare line F1 is installed separately There is an advantage to not have.

In addition, by installing the mixed-balance valve 300, the pressure of the high-pressure portion / the low-pressure portion can be made equilibrium within 30 seconds.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be taken by way of limitation, You will understand. Accordingly, the true scope of the invention should be determined only by the appended claims.

LP: Low pressure part HP: High pressure part
C1: Compressor C2: Compressor
S1: First point S2: Second point
S3: third point S4: fourth point
B1: first bypass line B2: second bypass line
B3: Third bypass line B4: Fourth bypass line
F1: first flare line F2: second flare line
110: first shutdown valve 120: first check valve
130: first scrubber 140: first compressor
150: first heat exchanger 160: first anti-surge valve
170: first blow-down valve 180: intermediate valve
230: second scrubber 240: second compressor
250: second heat exchanger 260: second anti-surge valve
270: second blow-down valve 280: second check valve
290: Second shutdown valve 300: Mixed-balance valve
400: Mixed-balance valve

Claims (5)

A first point provided between the first shutdown valve and the first compressor, a second point provided between the first compressor and the intermediate valve, a third point provided between the intermediate valve and the second compressor, And a fourth point provided between the second compressor and the second shutdown valve,
A first bypass line connecting between the first point and the second point;
A first anti-surge valve provided on the first bypass line;
A second bypass line connecting between a third point and a fourth point;
A second anti-surge valve provided on the second bypass line;
A third bypass line connecting between the first point and the fourth point; And
And a mixed-balance valve provided on the third bypass line,
And the first anti-surge valve, the second anti-surge valve, and the mixed-balance valve are opened together in an emergency to control the surge phenomenon. The method according to claim 1,
The first compressor and the second compressor
A scrubber on the inlet side,
And a heat exchanger is installed at the outlet side. The method according to claim 1,
The first compressor and the second compressor
And a heat exchanger and a scrubber are installed in order on the inlet side, respectively. 4. The method according to any one of claims 1 to 3,
At the second point, a first blow down valve is provided and a first flare line is connected to the first flare tower,
And at the fourth point a second blow down valve is provided and a second flare line is connected to the second flare tower. A first point provided between the first shutdown valve and the first compressor, a second point provided between the first compressor and the intermediate valve, a third point provided between the intermediate valve and the second compressor, And a fourth point provided between the first shutdown valve and the second shutdown valve,
A first bypass line connecting between the first point and the second point;
A first anti-surge valve provided on the first bypass line;
A second bypass line connecting between a third point and a fourth point;
A second anti-surge valve provided on the second bypass line;
A third bypass line connecting between the second point and the third point; And
And a mixed-balance valve provided on the third bypass line,
And the first anti-surge valve, the second anti-surge valve, and the mixed-balance valve are opened together in an emergency to control the surge phenomenon.

Images