KR20170143056A - Anti-surge valve control method of Multi gas Compressor Systems - Google Patents

Abstract

The present invention relates to a method to control an anti-surge valve of a parallel gas compressor system and, more specifically, relates to a method to control an anti-surge valve of a parallel gas compressor system, capable of controlling the anti-surge valve to prevent surge in the parallel gas compressor system. To achieve this, a method to control an anti-surge valve of a parallel gas compressor system formed with a plurality of gas compressors comprises: a load signal reception step of receiving information of a mass flowrate of gas required from a user; a first signal generation step of using the mass flowrate information of gas received in the load signal reception step to generate a signal to controller an anti-surge valve; a mass flowrate detection step of detecting the mass flowrate of gas sent to the compressor; a second signal generation step using the information detected in the mass flowrate detection step to generate a signal to control the anti-surge valve; a final signal generation step of generating a final signal based on the first and second signals generated in the first and second signal generation steps; and an anti-surge valve control step of finally controlling the anti-surge valve through the final signal generated in the final signal generation step.

Description

[0001] The present invention relates to an anti-surge valve control method for a gas compressor,

The present invention relates to a method for controlling an anti-surge valve in a parallel gas compressor system, and more particularly, to an anti-surge valve system for a parallel gas compressor system capable of efficiently controlling an anti- To a valve control method.

Generally, it is a machine for increasing the pressure of gas or air, and it discharges gas of high density to the resistance of the connecting device to operate a compressed air device, a rocker, or the pressure source of an air driving device.

Types of gas compressors include reciprocating, centrifugal, axial, gear, and screw systems.

Surge phenomena occur in such gas compressors depending on operating conditions.

Surge phenomenon means a state of unstable air flow through a compressor. When a flow lower than the rated flow rate is maintained, the discharge pressure of the compressor is relatively reduced compared to the pressure in the auxiliary pipe Reverse flow is formed into the compressor, and the flow amount of the discharge portion decreases with time, and the order in which the flow flows in the forward direction repeatedly repeats so rapidly that noise and vibration occur And causes mechanical damage to the compressor.

Therefore, in order to prevent the mechanical damage of the gas compressor, the gas compressor system is provided with a surge prevention system for preventing the surge phenomenon.

On the other hand, in a gas compressor, a parallel gas compressor in which a plurality of gas compressors are arranged in parallel to improve the efficiency is widely used.

1 is a schematic view schematically showing the configuration of a parallel gas compressor system for explaining an anti-surge valve control method of a conventional parallel gas compressor system.

1, in the conventional parallel gas compressor system, a plurality of gas compressors are arranged in parallel, one of the plurality of gas compressors is composed of a master gas compressor 1, and the remaining gas compressors are connected to a slave gas And a compressor (2).

Such a conventional parallel gas compressor system mainly includes a suction unit 10, a compression unit 20, a discharge unit 30, an anti-surge unit 40, and a pressure compensation unit 50.

The suction unit 10 includes a suction pipe 11 into which a supply gas flows, a first shutoff valve 12 provided in the suction pipe 11, a suction valve 13 for controlling a flow rate of gas introduced from the suction pipe 11, ).

Next, the compression unit 20 includes a compression pipe 21 for transferring the gas transferred from the suction unit 10, and a compressor 22 for compressing the gas to be transferred to the compression pipe 21 .

Next, the discharge unit 30 includes a discharge pipe 31 for transferring the gas compressed and discharged from the compression unit 20 to the use place, a check valve 31 for preventing the gas conveyed from the discharge pipe 31 from flowing backward, (32), and a second shut-off valve (33) installed in the discharge pipe (31).

Next, the anti-surge unit 40 flows into the circulation pipe 41, which is installed in the compression pipe 21, to recycle the gas compressed in the compression unit 20 when a surge occurs, An anti-surge controller (42) for measuring the flow rate of the gas flowing into the compressor (22) and controlling the anti-surge valve (42) And a signal selector 44 receiving the control signal of the anti-surge valve 42 transmitted from the anti-surge valve 43.

The pressure compensating unit 50 includes a pressure controller 51 for measuring the pressure of the discharged gas, a signal input unit 52 for receiving the pressure signal of the gas from the pressure controller 51, a signal input unit 52, And the signal is transmitted to the suction valve 13 and the anti-surge valve 42, so that the suction valve 13 and the anti- And a signal calculation section 44 for controlling the surge valve 42.

As described above, the conventional gas compressor system basically has a structure in which the gas is supplied through the suction unit 10 to control the flow rate of the gas, and the compressed gas is sent to the compression unit 20 to compress the gas and discharge it to the customer.

In this case, when the surge occurs during operation of the gas compressor, the anti-surge valve 42 of the anti-surge unit 40 operates to recycle the compressed gas back to the suction unit 10, And then controls the anti-surge valve 42 and the suction valve 13 to cope with the surge condition.

The signal selector 44 selects the signal S 1 transmitted from the signal calculator 53 and the signal S 2 transmitted from the anti-surge controller 43 to the anti- 42 to generate a final signal FS.

However, in the method of controlling the anti-surge valve of the conventional parallel gas compressor system, the method of generating the final signal FS for controlling the anti-surge valve 42 is not limited to the above- A signal 1 signal S1 generated using the load signal transmitted from the anti-surge controller 53 and a signal 2 signal S2 generated using the volume flow rate information measured by the anti-surge controller 43 are selected and applied And the final signal FS is used as a numerical value for setting the valve opening degree of the anti-surge valve 42.

2 is a table showing an example of an anti-surge valve opening change time point according to an anti-surge valve control method of a parallel gas compressor system of a conventional parallel gas compressor system.

Referring to FIG. 2, the change point of the final signal FS generated based on the signal 1 signal S1 and the signal 2 signal S2 according to the change of time can be confirmed.

2, in the conventional anti-surge valve control method of the parallel gas compressor system, the signal of the signal 1 (S1) and the signal 2 (S2) Is generated.

That is, assuming that the valve opening degree of the anti-surge valve 42 is 50% open to correspond to the log signal requested by the customer, the signal 1 signal S1 is 50% from the time of 1 to 5 blocks, As the signal 2 signal S2 is set to a value less than 50% (for example, 40%), the final signal FS is applied to the value of the signal 1 signal S1, Lt; / RTI >

However, since the signal 1 signal S1 is 50% from the time of 6 blocks, and the signal 2 signal S2 gradually increases to reach 60%, the final signal FS has a signal of a larger value 2 signal (S2) is applied to maintain the valve opening of 60%, there is a problem that it is difficult to quickly respond to a sudden change in the flow rate.

That is, the anti-surge valve 42 maintains the opening degree of 50% regardless of the change of the signal 2 signal S2 until the time of 5 blocks, and the anti-surge valve 42 operates from the time of 5 blocks, It is difficult to quickly respond to a point of occurrence, and a control delay occurs, and there is a problem that an impact is generated in the system of the gas compressor due to system instability and the compression efficiency of the gas is lowered.

SUMMARY OF THE INVENTION The present invention is conceived to solve the problems of the prior art described above, and it is an object of the present invention to provide a method and apparatus for controlling an anti-surge valve for preventing a surge condition during operation of a gas compressor, And an object of the present invention is to provide an anti-surge valve control method for a compressor system.

According to an aspect of the present invention, there is provided an anti-surge valve control method for a parallel gas compressor system comprising a plurality of gas compressors, the method comprising: transmitting information about a volume flow rate of a gas required by a customer Receiving a load signal; A signal 1 signal generation step of generating a signal for controlling the anti-surge valve using the volume flow rate information of the gas received in the load signal reception step; A volumetric flow rate sensing step of sensing a volumetric flow rate of the gas sent to the compressor; A signal 2 signal generation step of generating a signal for controlling the anti-surge valve using the information sensed in the volumetric flow rate sensing step; A final signal generation step of generating a final signal based on the signal 1 signal and the signal 2 signal generated in the signal 1 signal generation step and the signal 2 signal generation step; And an anti-surge valve control step of controlling the anti-surge valve finally through the final signal generated in the final signal generation step.

In this case, the signal 1 signal and the signal 2 signal are operation instruction information on the valve opening degree of the anti-surge valve.

The signal 1 signal and the signal 2 signal are sent to a signal selector, and the signal selector generates a final signal for finally controlling the anti-surge valve by judging the surge condition.

In addition, the final signal generated in the final signal generating step is a value increased by the signal 2 signal in the signal 1 signal.

The gas compressor may further include a load compensating step of compensating for the difference in relative value in the other gas compressors when the final signal is greater in the relative value than the signal 1 signal in the gas compressor of the plurality of gas compressors.

The anti-surge valve control method of the parallel gas compressor system according to the present invention has the following effects.

A signal 1 signal is generated using the volume flow information of the gas demanded by the customer, a signal 2 signal is generated after measuring a volume flow rate of gas introduced into the compressor, and an increased value of the signal 2 signal in the signal 1 It is possible to generate the final signal and to control the anti-surge valve through the final signal.

Accordingly, even if an unstable volumetric flow rate gradually occurs before a surge condition occurs, an immediate response is possible, thereby preventing a surge condition from occurring during operation of the gas compressor, thereby protecting the gas compressor system.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic view schematically showing the construction of a parallel gas compressor system for explaining an anti-surge valve control method of a conventional parallel gas compressor system; FIG.
FIG. 2 is a table showing an example of the time when the anti-surge valve opening changes according to the anti-surge valve control method of the parallel gas compressor system of the conventional parallel gas compressor system.
3 is a schematic view schematically showing a configuration of a parallel gas compressor system for explaining an anti-surge valve control method of a parallel gas compressor system according to the present invention.
4 is a flowchart showing an anti-surge valve control method of a parallel gas compressor system according to the present invention.
5 is a table showing an example of an anti-surge valve opening change timing according to the anti-surge valve control method of the parallel gas compressor system of the present invention.

The terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary meanings and the inventor may properly define the concept of the term to describe its invention in the best possible way And should be construed in accordance with the principles and meanings and concepts consistent with the technical idea of the present invention.

Hereinafter, preferred embodiments according to the present invention will be described in detail with reference to FIGS. 3 to 5 attached hereto.

FIG. 3 is a schematic view showing a configuration of a parallel gas compressor system for explaining an anti-surge valve control method of a parallel gas compressor system according to the present invention, and FIG. 4 is a block diagram of an anti- FIG. 5 is a table showing an example of an anti-surge valve opening change time point according to the anti-surge valve control method of the parallel gas compressor system of the present invention.

3, a parallel gas compressor system for explaining an anti-surge valve control method of a parallel gas compressor system according to the present invention comprises a plurality of gas compressors, one of which is a master gas compressor 100 And the remaining gas compressors may be composed of the slave gas compressors 200.

The parallel gas compressor system for explaining the anti-surge valve control method of the parallel gas compressor system according to the present invention includes a suction unit 110, a compression unit 120, a discharge unit 130, an anti-surge unit 140, and a pressure compensating unit 150.

The anti-surge valve control method of the parallel gas compressor system according to the present invention is a method for controlling the anti-surge valve for efficiently controlling the anti-surge valve in order to prevent the surge situation from occurring during operation of the gas compressor, To an anti-surge valve control method of a compressor system.

First, in the parallel type gas compressor system, the suction unit 110 is a portion that is supplied with gas such as LNG, CO2, N2, and H2S used as a working fluid of the gas compressor.

The suction unit 110 includes a suction pipe 111 for supplying the gases from a gas supply source (not shown).

The suction unit 110 may be disposed on the suction pipe 111 in order of a first shut-off valve 112 and a suction valve 113.

At this time, the suction pipe 111 is provided with a first shut-off valve 112 for blocking gas from flowing into the suction pipe 111. The gas is introduced into the gas compressor by interlocking with the second shut- To prevent gas from being introduced into or discharged from the gas compressor in order to temporarily stop the operation of the gas compressor and perform the maintenance work.

The first shut-off valve 112 may be a solenoid valve.

If necessary, the suction pipe 111 is provided with a pressure control valve (not shown) for controlling the pressure of the suction gas next to the first shut-off valve 112, and a gas (not shown) A condenser (not shown) for condensing may be further installed.

The suction valve 113 is installed in the suction pipe 111 after the first shut-off valve 112.

The suction valve 113 is a portion where the gas transferred from the first shut-off valve 112 is sucked, and is for controlling the flow rate of the gas transferred to the suction pipe 111.

The suction valves 113 and 213 are preferably formed of a suction throttling valve (STV) that sets the amount of gas passing through the suction valve 113 according to the degree of opening of the valve.

Inlet guide vanes (IGV) for controlling the flow rate of the suction unit 110 by adjusting the angle of the compressor vane by replacing the suction stroke valve, or by adjusting the speed of the compressor, And a variable speed driver (VSD) that adjusts the flow rate of the fluid 110.

The suction unit 110 regulates the pressure of the gas supplied to the suction unit 110, or controls the flow rate of the gas to send the compressed gas to the compression unit 120, which will be described later.

Next, the compression unit 120 is a unit for compressing the gas transferred from the suction unit 110. [

The compression unit 120 is provided with a compression pipe 121 to be connected to an end of the suction pipe 111 of the suction unit 110.

The compression pipe 121 is provided with a compressor 122.

The compressor 122 is a part for compressing the gas whose flow rate is controlled through the suction valve 113 to a high pressure state.

The compressor 122 compresses the gas transferred through the compression pipe 121 to generate and supply the gas at a high pressure through the mechanical energy.

A reciprocating motion, a centrifugal motion, an axial motion, and a screw motion may be applied depending on the operation of the compressor 122. [

Meanwhile, a separate cooler (not shown) may be installed in the compression pipe 121 to cool the compressed gas through the compressor 122 to a low temperature.

Next, the discharge part 130 is a part for discharging the compressed gas from the compression part 120 to the consumer.

The discharge unit 130 is installed with a discharge pipe 131 to be connected to the compression pipe 121.

Further, a relief valve (not shown) may be installed in the discharge pipe 131 to discharge the gas to the outside when an excessive pressure is generated in the gas compressor system.

Then, a check valve 132 is installed in the discharge pipe 132 to prevent the gas conveyed to the discharge pipe 131 from flowing back by the pressure difference.

The check valve 132 prevents the gas from flowing backward in a direction opposite to the position where the compression pipe 121 is located according to a change in the pressure in the discharge pipe 132 when a surge occurs.

Meanwhile, the discharge pipe 132 is provided with a check valve 132 followed by a second shutoff valve 133.

The second shut-off valve 133 interlocks with the first shut-off valve 112 of the suction unit 110 to prevent the gas from flowing into the discharge pipe 131 from the suction pipe 111 .

That is, when the maintenance work of any one of the plurality of gas compressors is required by blocking the suction pipe 111 corresponding to the inlet of the gas and the discharge pipe 131 discharging the gas, the first shutoff valve 112 And the second shut-off valve 133, as shown in Fig.

Next, the anti-surge unit 140 is a part for restoring the normal operation state when a surge phenomenon occurs in the gas compressor system, and serves to maintain the normal pressure by recirculating the gas pressure.

The anti-surge unit 140 mainly includes a circulation pipe 141, an anti-surge valve 142, an anti-surge controller 143, and a signal selector 144.

One end of the circulation pipe 141 is connected to the compression pipe 121 disposed between the compression unit 120 and the discharge unit 130 and the other end is connected to the rear end of the suction valve 113 of the suction unit 110 (Rear stage), that is, at a position corresponding to the back of the intake valve 113 based on the traveling direction in which the fluid flows.

The circulation pipe 141 recirculates the compressed gas delivered from the compression unit 120 to the compression pipe 121 disposed between the suction unit 110 and the compression unit 120.

At this time, an anti-surge valve 142 is installed in the circulation pipe 141 to control the flow of gas transferred to the circulation pipe 141.

That is, the gas flowing in and flowing through the circulation pipe 141 can be recirculated to the compression pipe 121 disposed between the suction unit 110 and the compression unit 120 according to the opening and closing of the anti-surge valve 142 It is.

Thus, by recirculating the gas to the compression pipe 121 through the circulation pipe 141, the pressure of the gas transferred to the compression pipe 121 can be increased to a certain level.

An anti-surge controller 143 for controlling the anti-surge valve 142 is installed in the suction pipe 111 between the suction valve 113 and the compressor 122, A signal selection unit 144 is provided.

The anti-surge controller 143 is a part for controlling the anti-surge valve 142 by measuring the flow rate or pressure of the gas introduced through the suction valve 113.

The signal measured through the anti-surge controller 143 is sent to the signal selector 144 and is controlled by determining whether the anti-surge valve 142 is open or not via the signal selector 144.

That is, the flow rate information collected through the anti-surge controller 143 can control the anti-surge valve 142 through the signal selector 144 to correspond to the load signal assigned to each gas compressor requested by the customer.

Here, the signal selector 144 may be a system logic that is applied in software.

As described above, the anti-surge valve 142 can improve the compression performance during normal operation, and when the surge occurs, the surge phenomenon can be quickly released and the normal pressure state can be maintained.

That is, when the surge phenomenon occurs, the anti-surge valve 142 is opened to circulate the gas, and when it is necessary to improve the gas compression performance in the normal operation, the anti-surge valve 142 is opened to circulate the gas .

Next, the pressure compensating unit 150 is a part for compensating the discharge pressure corresponding to the required pressure demanded by the customer.

The pressure compensating unit 150 measures a discharge pressure and compares the discharge pressure with a required pressure demanded by a customer to compensate the pressure value.

The pressure compensating unit 150 mainly includes a pressure controller 151, a signal input unit 152, and a signal calculating unit 144.

The pressure controller 151 is installed to be connected to a discharge pipe 131 which is transferred from the discharge unit 130 to a customer.

The pressure controller 151 is for measuring the pressure of the gas discharged through the second shut-off valve 133, and measures the discharge pressure to be delivered to the customer through the discharge part 130.

The signal input unit 152 receives the pressure signal of the gas from the pressure controller 151.

Also, the signal input unit 152 receives the pressure signal of the gas from the pressure controller 151 and the required pressure value of the customer at the same time.

The signal calculator 153 receives the discharge pressure signal of the gas and the required pressure value of the customer from the signal input unit 152 and calculates the pressure value of the gas pressure state requested by the customer.

That is, the signal calculation unit 153 calculates the pressure value of the gas pressure state requested by the customer using the discharge pressure signal of the gas and the demanded pressure value transmitted from the customer, and then the suction valve 113 and the anti-surge valve 142 to control the suction valve 113 and the anti-surge valve 142. At this time, signals are sent to the signal selector 144 and the suction valve 113, respectively, and the suction valve 113 and the anti- Thereby controlling the surge valve 142.

Therefore, the suction valve 113 and the anti-surge valve 142 can be separately controlled through the signal calculation unit 153.

Here, the signal calculation unit 153 may be a system logic that is applied in software.

As described above, the pressure of the discharged gas can be compared with the required pressure of the consumer through the pressure compensating unit 150, thereby preventing the occurrence of the anti-surge situation.

The signals transmitted from the signal input unit 152 to the signal calculation unit 153 in the master gas compressor 100 and the slave gas compressor 200 in the plurality of gas compressors are input to the pressure controller The demand signal of the slave gas compressor 200 may be a feed forward signal to which only the demand signal of the customer is delivered.

Hereinafter, the anti-surge valve control method in the above-described parallel gas compressor system will be described in detail.

4 is a flowchart showing an anti-surge valve control method of the parallel gas compressor system according to the present invention.

The method of controlling an anti-surge valve in a parallel gas compressor system according to the present invention includes steps of receiving a load signal S100, generating a signal 1 signal S200, detecting a volume flow rate S300, and generating a signal 2 signal S400 A final signal generating step S500, and an anti-surge valve control step S600.

The load signal receiving step (S100) is a step of receiving information on the volume flow rate of the gas required by the customer.

The load signal receiving step S100 receives the load signal for the volume flow information of the gas allocated to the discharge pressure of each gas compressor among the plurality of gas compressors from the destination.

That is, the load signal is transmitted from the destination to the signal input unit 152 in the load signal receiving step S100.

Next, the signal 1 signal generating step S200 is a step of generating a signal for controlling the anti-surge valve 142 using the volume flow rate information of the gas received in the load signal receiving step S100.

The signal 1 signal generation step S200 is a step of generating the signal 1 signal by controlling the signal calculation unit 153 to control the anti-surge valve 142 by sending the volume flow rate information transmitted to the signal input unit 152 to the signal calculation unit 153 Signal.

At this time, a signal generated by the signal calculator 153 to control the anti-surge valve 142 among the information transmitted from the signal input unit 152 becomes the signal 1 signal S1.

Therefore, the signal input unit 152 receives the volume flow rate information from the destination, and the information is sent to the signal calculation unit 153 to generate the signal 1 signal S1 for controlling the anti-surge valve 142.

Next, the volumetric flow rate sensing step (S300) is a step of sensing the volumetric flow rate of the gas sent to the compressor (122).

The volumetric flow rate sensing step S300 is a step of sensing the volumetric flow rate using the anti-surge controller 143 which is installed in the pipe before being introduced into the compressor 122 through the compression pipe 121.

The volumetric flow rate sensing step S300 is a step of sensing a volumetric flow rate before entering the compressor 122 using the anti-surge controller 143, and judging the flow of the gas conveyed through the compression pipe 121 .

Next, the signal 2 signal generation step S400 is a step of generating a signal for controlling the anti-surge valve 142 using the information sensed in the volume flow sensing step S300.

In the volume flow rate sensing step S300, a signal for controlling the anti-surge valve 142 is generated in the signal 2 signal generation step S400 using the volume flow rate information sensed through the anti-surge controller 143. [

The signal generated in the signal 2 signal generation step S400 is a signal 2 signal S2.

As described above, the signal 1 signal S1 and the signal 2 signal S2 are generated in the signal 1 signal generation step S200 and the signal 2 signal generation step S400, and the signal 1 signal S1 and the signal 2 signal S2 are generated. (S2) is used as a signal for controlling the anti-surge valve (142).

The signal 1 signal S1 and the signal 2 signal S2 are used as operation instruction information on the valve opening degree of the anti-surge valve 142.

Next, the final signal generating step S500 is a step of generating a final signal S500 based on the signal 1 signal S1 and the signal 2 signal S2 generated in the signal 1 signal generating step S200 and the signal 2 signal generating step S400, (FS).

The final signal generation step S500 includes a signal 1 signal S1 generated and transmitted from the signal calculation unit 153 and a signal 2 signal S2 generated and transmitted from the anti-surge controller 143, A process of generating a final signal FS for controlling the surge valve 142 is performed.

In the final signal generation step S500, the signal 1 signal S1 and the signal 2 signal S2 are sent to the signal selection unit 144, and the signal selection unit 144 determines whether the surge situation And finally generates a final signal FS for controlling the anti-surge valve 142.

That is, the final signal FS can be finally determined in consideration of the signals of the signal 1 signal S1 and the signal 2 signal S2.

The final signal (FS) generated in the final signal generation step (S500) is transmitted to the anti-surge valve (142).

Here, the final signal FS may be a value increased by the signal 2 signal S2 from the signal 1 signal S1.

The final signal FS will be described in detail with reference to FIG.

Next, the anti-surge valve control step S600 is a step of finally controlling the anti-surge valve 142 through the final signal FS generated in the final signal generating step S500.

The anti-surge valve control step S600 is a step in which the finally determined final signal FS is transmitted to the anti-surge valve 142 to control the operation of the anti-surge valve 142.

In the anti-surge valve control step S600, the operation of the actual anti-surge valve 142 is determined using the information of the signal 2 signal S2 in the signal 1 signal S1.

5 is a table showing an example of an anti-surge valve opening change time point according to the anti-surge valve control method of the parallel gas compressor system of the present invention.

Referring to FIG. 5, the change point of the final signal FS generated based on the signal 1 signal S1 and the signal 2 signal S2 according to the change of time can be confirmed.

5, in the anti-surge valve control method of the parallel gas compressor system of the present invention, the final signal FS is generated by using the signal 1 signal S1 and the signal 2 signal S2, Here, the final signal FS is a value increased from the signal 1 signal S1 by the signal 2 signal S2.

That is, assuming that the valve opening degree of the anti-surge valve 42 is 50% opened to correspond to the log signal requested by the customer, the signal 1 signal S1 is 50% until the time of one block, When the signal S2 is set to 0%, the final signal FS is maintained at 50%, the state of the anti-surge valve 142 is kept unchanged, and the signal S2 is changed from the time of 2 blocks to the signal 2 It can be confirmed that the final signal FS is set correspondingly to the increased amount.

As a result, the time at which the signal 2 signal S2 changes from the time of two blocks becomes a time point at which the anti-surge valve 142 changes its opening degree.

That is, the anti-surge valve control method of the parallel gas compressor system according to the present invention can immediately respond to the change of the signal 2 signal S2, and even if an anti-surge situation occurs, It becomes possible to respond quickly.

Meanwhile, the anti-surge valve control method of the parallel gas compressor system according to the present invention may further include a load compensation step (S700).

In the load compensating step S700, when the final signal FS of one of the plurality of gas compressors is greater than the signal 1 signal S1, the other gas compressor compensates for the difference of the relative value in the other gas compressors .

That is, when the anti-surge valve 142 has an increased volume flow rate relative to the load signal, corresponding to the signal 2 signal S2 as in the embodiment of FIG. 5, So that the sum of the flow rates discharged from the respective gas compressors is finally set to a flow rate required by the customer.

Hereinafter, the operation sequence of the anti-surge valve control method of the parallel gas compressor system according to the present invention will be described with reference to FIG.

First, the signal input unit 152 receives a load signal signal requested by a customer.

The signal calculation unit 153 receives the signal signal from the signal input unit 152 and sends a signal 1 signal S1 for controlling the anti-surge valve 142 to the signal selection unit 144.

Then, the anti-surge controller 143 generates the signal 2 signal S2 by using the sensed volume flow rate information and sends it to the signal selector 144.

The signal selector 144 then uses the signal 1 signal S 1 and the signal 2 signal S 2 to generate the final signal FS of an increased amount of the signal 2 signal S 2 relative to the signal 1 signal S 1, And transmits the final signal FS to the anti-surge valve 142 to control the anti-surge valve 142.

As described above, the signal 1 signal S1 is generated using the volume flow rate information of the gas requested by the customer, the volume flow rate of the gas flowing into the compressor 122 is measured, and the signal 2 signal S2 is generated The anti-surge valve 142 can be controlled through the final signal FS by generating the final value of the signal 2 signal S2 in the signal 1 signal S1 as the final signal FS.

Accordingly, even if an unstable volume flow rate gradually occurs before the surge condition occurs, the gas compressor system can be protected by preventing the occurrence of a surge condition during operation of the gas compressor.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. .

S100: Receive the load signal
S200: signal 1 signal generation step
S300: Volume flow sensing step
S400: Signal 2 signal generation step
S500: Final signal generation step
S600: Anti-surge valve control step
S700: Load Compensation Phase

Claims (5)

A method of controlling an anti-surge valve in a parallel gas compressor system comprising a plurality of gas compressors,
A load signal receiving step of receiving information on a volume flow rate of a gas required by a customer;
A signal 1 signal generation step of generating a signal for controlling the anti-surge valve using the volume flow rate information of the gas received in the load signal reception step;
A volumetric flow rate sensing step of sensing a volumetric flow rate of the gas sent to the compressor;
A signal 2 signal generation step of generating a signal for controlling the anti-surge valve using the information sensed in the volumetric flow rate sensing step;
A final signal generation step of generating a final signal based on the signal 1 signal and the signal 2 signal generated in the signal 1 signal generation step and the signal 2 signal generation step;
And an anti-surge valve control step of controlling the anti-surge valve finally through the final signal generated in the final signal generation step. The method according to claim 1,
Wherein the signal 1 signal and the signal 2 signal are operating indication information on the valve opening degree of the anti-surge valve. The method according to claim 1,
Wherein the signal 1 signal and the signal 2 signal are sent to a signal selector and the signal selector generates a final signal for finally controlling the anti-surge valve by judging the surge condition. Of the anti-surge valve. The method according to claim 1,
Wherein the final signal generated in the final signal generating step includes:
Wherein the value of the signal 1 signal is increased by the signal 2 signal in the signal 1 signal. The method according to claim 1,
And a load compensating step of compensating for a difference in relative value in other gas compressors when a final signal in the gas compressor of any one of the plurality of gas compressors has a relative value greater than that of the signal 1 signal, A method of controlling an anti-surge valve in a system.

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