KR101836556B1 - A Treatment System Of Liquefied Gas - Google Patents

Abstract

The present invention relates to a liquefied gas processing system, comprising: a liquefied gas supply line connecting a liquefied gas storage tank and a demander; A bypass line branched on the liquefied gas supply line; A fuel pump provided on the liquefied gas supply line and supplying liquefied gas to the customer; A sensor provided on the liquefied gas supply line and measuring a pressure or a flow rate of the liquefied gas flowing in the liquefied gas supply line; A discharge valve located downstream of a point where the bypass line is branched on the liquefied gas supply line; And a control unit for controlling the discharge valve or the fuel pump by comparing a required value of the liquefied gas of the demander with a pressure value or a flow rate value measured by the sensor.
The liquefied gas processing system according to the present invention has a variable capacity pump to control the pump operation power according to the amount of fuel consumed by the customer, thereby minimizing the power consumption of the system and optimizing the energy consumption accordingly. Further, the durability of the pump is improved and the service life is increased, and the control reliability of the pump is improved.

Description

Description of the Related Art A Treatment System Of Liquefied Gas

The present invention relates to a liquefied gas processing system.

A ship is a means of transporting large quantities of minerals, crude oil, natural gas, or more than a thousand containers. It is made of steel and buoyant to float on the water surface. ≪ / RTI >

Such a vessel generates thrust by driving the engine. In this case, the engine uses gasoline or diesel to move the piston so that the crankshaft is rotated by the reciprocating motion of the piston, so that the shaft connected to the crankshaft is rotated to drive the propeller It was common.

In recent years, however, LNG fuel supply systems for driving an engine using LNG as a fuel have been used in an LNG carrier carrying Liquefied Natural Gas (LNG) It is also applied to other ships.

In general, LNG is a clean fuel and reserves are richer than petroleum, and its use is rapidly increasing as mining and transportation technology develops. This LNG is generally stored in a liquid state at a temperature of -162 ° C. or below under 1 atm. The volume of liquefied methane is about one sixth of the volume of methane in a gaseous state, The specific gravity is 0.42, which is about one half of that of crude oil. However, the temperature and pressure required to drive the engine may be different from the state of the LNG stored in the tank. Therefore, the technology of controlling the temperature and pressure of the LNG stored in the liquid state and supplying it to the engine is being studied.

In such a system for supplying liquefied gas, a pump is mainly used to transfer the liquefied gas to a customer site or to pressurize the liquefied gas. However, since the pump is always driven to the rated value, the discharge pressure of the liquefied gas is mainly made by the bypass valve, and there is a problem that a lot of power loss occurs due to unnecessary driving of the pump.

An object of the present invention is to provide a liquefied gas processing system for minimizing the power consumption of a pump by providing a variable displacement pump.

A liquefied gas processing system according to an embodiment of the present invention includes a liquefied gas supply line for connecting a liquefied gas storage tank and a demander; A bypass line branched on the liquefied gas supply line; A fuel pump provided on the liquefied gas supply line and supplying liquefied gas to the customer; A sensor provided on the liquefied gas supply line and measuring a pressure or a flow rate of the liquefied gas flowing in the liquefied gas supply line; A discharge valve located downstream of a point where the bypass line is branched on the liquefied gas supply line; And a control unit for controlling the discharge valve or the fuel pump by comparing a required value of the liquefied gas of the demander with a pressure value or a flow rate value measured by the sensor.

Specifically, the fuel pump is a variable displacement pump, and can change the flow rate or pressure of the liquefied gas discharged according to the supply of electric power.

Specifically, the control unit increases the opening degree of the discharge valve and increases the supply power to the fuel pump when the amount of liquefied gas required by the demanding party is greater than the predetermined amount of liquefied gas required, The opening degree of the discharge valve can be reduced and the supply power to the fuel pump can be reduced.

Specifically, a high pressure pump that receives liquefied gas from the fuel pump and compresses it at a high pressure; And a heat exchanger for vaporizing the liquefied gas discharged from the high-pressure pump.

Specifically, the sensor includes: a first sensor provided between the customer and the heat exchanger; A second sensor provided between the discharge valve and the high-pressure pump; And a third sensor provided between the discharge valve and the fuel pump.

Specifically, the control unit examines a value measured by the second sensor when a value measured by the first sensor is greater than a first predetermined value, and when the value measured by the second sensor is a second Increasing the opening degree of the discharge valve and examining a value measured by the third sensor, and when the value measured by the third sensor is lower than the third predetermined value, Can be increased.

Specifically, the control unit examines a value measured by the second sensor when the value measured by the first sensor is smaller than a first preset value, and when the value measured by the second sensor is less than a second predetermined value, And when the value measured by the third sensor is higher than the third predetermined value, the control unit controls the fuel pump to measure the electric power Can be reduced.

Specifically, the bypass valve may further include a bypass valve provided on the bypass line.

Specifically, the bypass valve can maintain the opening degree when the amount of liquefied gas required by the demanding customer is smaller than the required amount of liquefied gas and the opening degree of the discharge valve is reduced.

The liquefied gas processing system according to the present invention has a variable capacity pump to control the pump operation power according to the amount of fuel consumed by the customer, thereby minimizing the power consumption of the system and optimizing the energy consumption accordingly. Further, the durability of the pump is improved and the service life is increased, and the control reliability of the pump is improved.

1 is a conceptual diagram of a liquefied gas processing system according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a conceptual diagram of a liquefied gas processing system according to an embodiment of the present invention.

1, a liquefied gas processing system 1 according to an embodiment of the present invention includes a liquefied gas storage tank 10, a customer 20, a pump 30, a heat exchanger 40, a control unit 50, sensors 61, 62, 63, and valves 71, 72.

Hereinafter, the LNG may be used to encompass not only a liquid state NG but also a NG state such as a supercritical state for the sake of convenience. The evaporation gas may include not only gaseous state evaporation gas but also liquefied evaporation gas Can be used as a meaning.

(Not shown) pressurizes the liquefied gas discharged from the liquefied gas storage tank (not shown) from several to several tens of bar, and then the high-pressure pump (not shown) (Not shown) pressurizes the liquefied gas at a pressure (for example, 200 bar to 400 bar) required by a customer (not shown) and supplies the pressurized liquefied gas to a heat exchanger (not shown). Then, the heat exchanger may increase the temperature of the liquefied gas supplied from the high-pressure pump, and then supply the liquefied gas in the supercritical state to the customer. At this time, the liquefied gas supplied to the customer can have a supercritical state having a pressure of 200 to 400 bar and a temperature of 30 to 60 degrees.

At this time, the boosting pump was always driven at rated speed and always discharged constant pressure or constant flow rate of liquefied gas. The pressure of the liquefied gas discharged from the booster pump and flowing on the liquefied gas supply line (not shown) was regulated by a discharge valve (not shown) or a bypass valve (not shown).

Therefore, the booster pump does not vary according to the required pressure or required flow rate of the liquefied gas during driving, and thus, even when the required amount of liquefied gas is reduced or the required pressure is reduced, there is a problem that unnecessary driving is performed and power loss is increased. In addition, the booster pump has a problem that durability is weakened by unnecessary driving, and thus the life is shortened, and the driving reliability is reduced.

The liquefied gas storage tank (10) stores liquefied gas to be supplied to the customer (20). The liquefied gas storage tank 10 must store the liquefied gas in a liquid state, at which time the liquefied gas storage tank 10 may have the form of a pressure tank.

The liquefied gas storage tank 10 includes an outer tank (not shown), an inner tank (not shown), and a heat insulating portion (not shown). The outer tank is a structure that forms the outer wall of the liquefied gas storage tank 10, and may be formed of steel, and may have a polygonal cross section.

The inner tank is provided inside the outer tank, and can be supported and supported inside the outer tank by a support (not shown). At this time, the support may be provided on the lower end of the inner tank, and may be provided on the side of the inner tank for suppressing lateral movement of the inner tank.

The inner tank can be made of stainless steel and can be designed to withstand pressures from 5 bar to 10 bar (6 bar, for example). The reason why the inner tank is designed to withstand such a constant pressure is that the inner pressure of the inner tank can be increased as the liquefied gas contained in the inner tank is evaporated and the evaporation gas is generated.

A baffle (not shown) may be provided in the inner tank. The baffle means a plate in the form of a lattice. As the baffle is installed, the pressure inside the tank can be evenly distributed to prevent the tank pressure from being concentrated to a part of the tank.

The heat insulating portion is provided between the inner tank and the outer tank and can prevent the external heat energy from being transmitted to the inner tank. At this time, the heat insulating portion may be in a vacuum state. By forming the thermal insulation in a vacuum, the liquefied gas storage tank 10 can withstand higher pressures more efficiently than a conventional tank. For example, the liquefied gas storage tank 10 can sustain a pressure of 5 to 20 bar through the vacuum insulation.

As described above, in this embodiment, the use of the pressure tank type liquefied gas storage tank 10 having a vacuum type heat insulating portion between the outer tanks and the inner tank makes it possible to minimize the generation of the evaporated gas, It is possible to prevent a problem such as breakage of the storage tank 10 from occurring.

A liquefied gas supply line 11 for supplying a liquefied gas may be provided between the liquefied gas storage tank 10 and the customer 20 and a liquefied gas supply line 11 may be provided in the liquefied gas supply line 11, 30, a heat exchanger 40, and the like, so that the liquefied gas can be supplied to the customer 20.

At this time, a liquefied gas supply valve (not shown) is provided in the liquefied gas supply line 11, and the liquefied gas supply amount can be adjusted according to the opening degree of the liquefied gas supply valve.

Further, in one embodiment of the present invention, the apparatus may further include a bypass line 12 branched on the liquefied gas supply line 11. The bypass line 12 branches off from the liquefied gas supply line 11 and is connected to the liquefied gas storage tank 10. The bypass line 12 is connected to the liquefied gas supply line 11, So that at least some of the liquefied gas flowing in the liquefied gas storage tank (10) can return.

The customer 20 is driven through the liquefied gas supplied from the liquefied gas storage tank 10. That is, the consumer 20 needs liquefied gas and is driven using the raw material as the raw material. The consumer 20 may be an engine (not shown), a boiler (not shown), a GCU (not shown), and the like.

The consumer 20 may be an ME-GI engine (not shown) in the case of an engine, or a dual fuel engine (not shown). When the customer 20 is a dual fuel engine, liquefied gas or fuel oil can be selectively supplied without being mixed with liquefied gas and fuel oil. This is to prevent the mixture of two materials having different combustion temperatures from being mixed, thereby preventing the efficiency of the engine from deteriorating.

As the piston (not shown) inside the cylinder (not shown) reciprocates by the combustion of the liquefied gas, the engine rotates the crankshaft (not shown) connected to the piston and the shaft Can be rotated. Accordingly, as the propeller (not shown) connected to the shaft finally rotates at the time of driving the engine, the hull (not shown) moves forward or backward.

The consumer 20 described above is an example of an engine, and the consumer 20 is not limited thereto and can be variously applied where the liquefied gas is needed.

The pump 30 is provided on the liquefied gas supply line 11 and can supply the liquefied gas to the customer 20. Specifically, the pump 30 may be composed of a fuel pump 31 and a high-pressure pump 32. [

The fuel pump 31 may be provided on the liquefied gas supply line 11 between the liquefied gas storage tank 10 and the high pressure pump 32 or may be provided in the liquefied gas storage tank 10 as a submerged pump And a sufficient amount of liquefied gas can be supplied to the high-pressure pump 32, thereby preventing cavitation in the high-pressure pump 32.

Further, the fuel pump 31 can extract the liquefied gas from the liquefied gas storage tank 10 and pressurize the liquefied gas within several to several tens of bar.

In the embodiment of the present invention, the fuel pump 31 can change the pressure or the flow rate discharged according to the supply of electric power to the variable displacement pump. For example, the fuel pump 31 increases the pressure or flow rate of the liquefied gas discharged in proportion to the amount of electric power that is supplied when the electric power to be supplied increases, and when the supplied electric power becomes smaller, The pressure or the flow rate of the liquefied gas is reduced.

The amount of electric power supplied to the fuel pump 31 by the control unit 50 can be adjusted by connecting the fuel pump 31 with a control unit 50 to be described later.

The high pressure pump 32 may be provided on the liquefied gas supply line 11 between the fuel pump 31 and a heat exchanger 40 to be described later and pressurizes the liquefied gas to a high pressure.

The high pressure pump 32 can pressurize the liquefied gas discharged from the fuel pump 31 to a high pressure to supply the liquefied gas to the customer 20. The liquefied gas is supplied from the liquefied gas storage tank 10 to the fuel pump 31 at a pressure of about 10 bar and then pressurized by the fuel pump 31. The high pressure pump 32 is supplied to the fuel pump 31 The pressurized liquefied gas in the liquid state can be secondarily pressurized and supplied to the heat exchanger 40.

At this time, the high-pressure pump 32 pressurizes the liquefied gas to a pressure required by the customer 20 (for example, 200 bar to 400 bar) and supplies the liquefied gas to the customer 20 so that the customer 20 can use the liquefied gas .

The high-pressure pump 32 pressurizes the liquid-state liquefied gas discharged from the fuel pump 31 at a high pressure, so that the liquefied gas becomes a supercritical state having a temperature higher than the critical point and a high pressure, . At this time, the temperature of the liquefied gas in the supercritical state may be below minus 20 degrees Celsius, which is relatively higher than the critical temperature.

Alternatively, the high-pressure pump 32 can pressurize the liquefied gas in the liquid state to a super-cooled liquid state by pressurizing it at a high pressure. Here, the liquefied gas in the subcooled liquid state is a state in which the pressure of the liquefied gas is higher than the critical pressure and the temperature is lower than the critical temperature.

Specifically, the high-pressure pump 32 pressurizes the liquid-state liquefied gas discharged from the fuel pump 31 to a high pressure from 200 bar to 400 bar (preferably 300 bar) so that the temperature of the liquefied gas becomes lower than the critical temperature So that the liquefied gas can be phase-changed into a subcooled liquid state. Here, the temperature of the liquefied gas in the subcooled liquid state may be minus 140 degrees Celsius to minus 60 degrees Celsius, which is relatively lower than the critical temperature.

The heat exchanger 40 is provided on the liquefied gas supply line 11 between the customer 20 and the pump 30 and heats the liquefied gas supplied from the pump 30. The pump 30 for supplying the liquefied gas to the heat exchanger 40 may be a high pressure pump 32 and the heat exchanger 40 may supply the liquefied gas in the subcooled liquid state or the supercritical state to the pressure (200 bar) to 400 bar (preferably 300 bar), and is converted into a liquefied gas in a supercritical state of 30 to 60 degrees and then supplied to the customer 20.

The heat exchanger 40 heats the liquefied gas using glycol water supplied from steam or a glycol heater (not shown) supplied through a boiler (not shown), or heats the liquefied gas using electric energy Or it can heat the liquefied gas using waste heat generated from a generator (not shown) or other facilities provided in a ship (not shown).

The control unit 50 compares the liquefied gas required amount of the customer 20 with the pressure value or the flow rate value measured by the sensors 61, 62 and 63 and controls the discharge valve 71 or the fuel pump 31 .

That is, the control unit 50 receives the measured values from the sensors 61, 62, and 63 to be described later by wire or wirelessly and wirelessly transmits them to the discharge valve 71, the bypass valve 72, Or by wirelessly transmitting a control signal.

Specifically, the control unit 50 increases the opening degree of the discharge valve 71 and increases the amount of electric power supplied to the fuel pump 31 when the liquefied gas required amount of the demander 20 is higher than the predetermined liquefied gas required amount, The opening degree of the discharge valve 71 is reduced and the amount of electric power supplied to the fuel pump 31 is reduced.

The control of the controller 50 may be controlled through the measurement values of the sensors 61, 62, and 63, which will be described in detail below.

The control unit 50 examines the value measured by the second sensor 62 when the value measured by the first sensor 61 is higher than the first preset value and the value measured by the second sensor 62 The value measured by the third sensor 63 is compared with the value measured by the third sensor 63. If the value measured by the second sensor 63 is greater than the second predetermined value, The supply of electric power to the fuel pump 31 can be increased.

The control unit 50 examines the value measured by the second sensor 62 when the value measured by the first sensor 61 is lower than the first preset value, ) Is less than the second predetermined value, the opening degree of the discharge valve 71 is reduced and the value measured by the third sensor 63 is examined. When the value measured by the third sensor 63 is smaller than the second predetermined value, The supply of electric power to the fuel pump 31 can be reduced.

When the amount of liquefied gas required by the consumer 20 is increased, the measured value of the first sensor 61 becomes smaller and the measured value measured by the second sensor 62 sequentially becomes smaller. Accordingly, if the opening degree of the discharge valve 71 is reduced under the control of the control unit 50, the flow rate or pressure of the liquefied gas discharged from the fuel pump 31 is constant, The value becomes larger.

That is, in this case, it means that the fuel pump 31 discharges the liquefied gas unnecessarily, and accordingly, the fuel pump 31 wastes the electric power to be operated, the durability is weakened by unnecessary driving, and the energy loss .

Therefore, in the embodiment of the present invention, when the measured value measured by the third sensor 63 becomes larger through the control unit 50, the amount of electric power supplied to the fuel pump 31 is reduced, The driving force can be reduced, the energy can be effectively used, the power can be used optimally, and the durability of the fuel pump 31 is enhanced, thereby extending the service life.

The sensors 61, 62 and 63 are provided on the liquefied gas supply line 11 and measure the pressure or the flow rate of the liquefied gas flowing in the liquefied gas supply line 11. [

Specifically, the sensors 61, 62, and 63 are provided between the customer 20 and the heat exchanger 40, the first sensor 61, the discharge valve 71, and the high-pressure pump 32 And a third sensor 63 provided between the second sensor 62 and the discharge valve 71 and the fuel pump 31.

The first sensor 61 can measure the flow rate or pressure of the liquefied gas supplied to the customer 20 and transmit it to the control unit 50 by wire or wirelessly.

The flow rate or the pressure value of the liquefied gas measured by the first sensor 61 becomes small when the amount of liquefied gas required by the customer 20 is increased and the first sensor 61 measures The flow rate or the pressure of the liquefied gas is increased.

The second sensor 62 can measure the flow rate or pressure of the liquefied gas discharged from the discharge valve 71 and transmit it to the control unit 50 by wire or wirelessly.

When the amount of liquefied gas required by the consumer 20 is increased, the measured value of the first sensor 61 becomes smaller and the measured value measured by the second sensor 62 sequentially becomes smaller. In addition, if the amount of liquefied gas required by the consumer 20 is reduced, the measured value of the first sensor 61 becomes larger, and the measured value measured by the second sensor 62 sequentially increases accordingly.

This is because the amount of the liquefied gas consumed by the customer 20 is suddenly increased when the amount of liquefied gas required by the customer 20 is increased so that the liquefied gas is supplied from the liquefied gas supply line 11, The pressure or the flow rate of the refrigerant is reduced.

On the other hand, if the amount of liquefied gas required by the consumer 20 is reduced, the amount of liquefied gas consumed by the consumer 20 is suddenly reduced. As a result, the liquefied gas is supplied from the liquefied gas supply line 11, The gas pressure or flow rate value becomes large.

The third sensor 63 can measure the flow rate or pressure of the liquefied gas discharged from the fuel pump 31 and transmit it to the control unit 50 by wire or wirelessly.

When the amount of liquefied gas required by the consumer 20 is increased, the measured value of the first sensor 61 becomes smaller and the measured value measured by the second sensor 62 sequentially becomes smaller. Accordingly, if the opening degree of the discharge valve 71 is reduced under the control of the control unit 50, the flow rate or pressure of the liquefied gas discharged from the fuel pump 31 is constant, The value becomes larger.

In addition, if the amount of liquefied gas required by the consumer 20 is reduced, the measured value of the first sensor 61 becomes larger, and the measured value measured by the second sensor 62 sequentially increases accordingly. Therefore, if the opening degree of the discharge valve 71 is increased under the control of the control unit 50, the flow rate or pressure of the liquefied gas discharged from the fuel pump 31 is constant, The value becomes smaller.

The valves 71 and 72 include a discharge valve 71 and a bypass valve 72.

The discharge valve 71 is located downstream of the branch point of the bypass line 12 on the liquefied gas supply line 11. That is, the discharge valve 71 can be provided on the liquefied gas supply line 11 between the branch point of the bypass line 12 and the high-pressure pump 32.

The discharge valve 71 can control the amount of liquefied gas discharged from the liquefied gas storage tank 10 to be supplied to the high-pressure pump 32. In other words, the discharge valve 71 can receive the command from the control unit 50 by wire or wirelessly, and can control the opening degree of the discharge valve 71. The opening amount of the discharge valve 71 can be controlled by supplying the liquefied gas to the high-

The bypass valve 72 may be provided on the bypass line 12. When the required amount of liquefied gas of the customer 20 is lower than the required amount of the liquefied gas and the opening degree of the discharge valve 71 is reduced, The opening degree can be maintained. That is, even if the opening degree of the discharge valve 71 is reduced, the bypass valve 72 can maintain its opening degree in order to maintain the minimum flow rate.

The bypass valve 72 can regulate the amount by which the liquefied gas discharged from the liquefied gas storage tank 10 returns to the liquefied gas storage tank 10 again. At this time, the bypass valve 72 can receive the command from the control unit 50 in a wired or wireless manner to adjust the opening degree, and the amount of the liquefied gas returned to the liquefied gas storage tank 10 .

As described above, the liquefied gas processing system 1 according to the present invention includes the variable displacement pump 31 to control the operating power of the fuel pump 31 according to the fuel consumption amount of the customer 20, 1) can be minimized and the energy consumption can be optimized.

Further, the durability of the fuel pump 31 is improved and the service life is increased, and the control reliability of the fuel pump 31 is improved.

1: liquefied gas processing system 10: liquefied gas storage tank
11: Liquefied gas supply line 12: Bypass line
20: customer 30: pump
31: fuel pump 32: high pressure pump
40: heat exchanger 50:
61: first sensor 62: second sensor
63: Third sensor 71: Discharge valve
72: Bypass valve

Claims (9)

A liquefied gas supply line connecting the liquefied gas storage tank and the customer;
A bypass line branched on the liquefied gas supply line;
A fuel pump provided on the liquefied gas supply line and supplying liquefied gas to the customer;
A sensor provided on the liquefied gas supply line and measuring a pressure or a flow rate of the liquefied gas flowing in the liquefied gas supply line;
A discharge valve located downstream of a point where the bypass line is branched on the liquefied gas supply line; And
And a controller for controlling the discharge valve or the fuel pump by comparing a required value of the liquefied gas of the demander with a pressure value or a flow rate value measured by the sensor,
The fuel pump includes:
A variable displacement pump for changing a flow rate or a pressure of a liquefied gas discharged according to a supply of electric power,
Wherein,
The control unit compares the required amount of liquefied gas of the customer with the pressure value or the flow rate value measured by the sensor to primarily control the opening of the discharge valve and secondarily controls the flow rate or pressure of the liquefied gas discharged from the fuel pump Wherein the liquefied gas processing system comprises: delete The apparatus of claim 1,
Increases the opening degree of the discharge valve and increases the supply power to the fuel pump when the liquefied gas required amount of the demander increases from a predetermined liquefied gas required amount,
Wherein the opening degree of the discharge valve is reduced and the supply power to the fuel pump is reduced when the amount of the liquefied gas required by the demander decreases from the predetermined liquefied gas required amount. The method of claim 3,
A high pressure pump that receives liquefied gas from the fuel pump and compresses the liquefied gas to a high pressure; And
Further comprising a heat exchanger for vaporizing the liquefied gas discharged from the high-pressure pump. 5. The sensor according to claim 4,
A first sensor provided between the customer and the heat exchanger;
A second sensor provided between the discharge valve and the high-pressure pump; And
And a third sensor provided between the discharge valve and the fuel pump. 6. The apparatus of claim 5,
A value measured by the second sensor is checked when the value measured by the first sensor is greater than a first predetermined value,
And when the value measured by the second sensor is higher than the second predetermined value, the opening degree of the discharge valve is increased and the value measured by the third sensor is examined
And increases the supply of electric power to the fuel pump when the value measured by the third sensor is lower than the third predetermined value. 6. The apparatus of claim 5,
A value measured by the second sensor is examined when a value measured by the first sensor is smaller than a first predetermined value,
If the value measured by the second sensor is greater than the second predetermined value, the opening degree of the discharge valve is reduced and then the value measured by the third sensor is examined
And when the value measured by the third sensor is higher than a third predetermined value, the supply of electric power to the fuel pump is reduced. The method according to claim 1,
Further comprising a bypass valve disposed on the bypass line. 9. The apparatus according to claim 8,
Wherein when the amount of the liquefied gas required by the customer is lower than the predetermined liquefied gas required amount and the opening degree of the discharge valve is reduced, the opening degree is maintained.

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