GR20210100621A - Compressor unit and control unit thereof - Google Patents

Abstract

A compressor unit includes a first reciprocating compressor, a second reciprocating compressor connected in parallel with the first reciprocating compressor, and a control unit. The first reciprocating compressor includes a first check valve, a first pressure sensor, a first bypass flow channel, and a first bypass valve. The second reciprocating compressor includes a second check valve, a second pressure sensor, a second bypass flow channel, and a second bypass valve. The control unit controls an opening degree of the first bypass valve to cause detection pressure of the first pressuresensor to be a first setting value, and controls an opening degree of the second bypass valve to cause detection pressure of the second pressure sensor to be a second setting value lower than the first setting value.

Description

COMPRESSOR UNIT AND COMPRESSOR UNIT CONTROL PROGRAM

Technical field

[0001]

The present invention relates to a compressor unit and a compressor unit control program.

Background technique

[0002]

Conventionally, a compressor unit is known to be used to compress the evaporation losses created by the evaporation of a liquefied gas in a storage tank of a vessel carrying liquefied natural gas (LNG) or other similar medium. Some compressor units of this type include a plurality of multistage compressors installed in parallel. In this compressor unit, the gas discharged from each compressor is supplied to a demand destination, such as an engine.

[0003]

This type of technology is disclosed in Laid-Open Japanese Patent Application No. 2018-518415, in Japanese Patent Application Laid-Open No. 2018-534206 and Japanese Published Patent Application No. 2019-11735. Published Japanese Patent Application No. 2018-518415 discloses an evaporative loss compressor installed in LNG carriers and other similar vehicles. In this evaporative loss compressor, a reciprocating compressor and a centrifugal compressor are provided in parallel. Published Japanese Patent Application No.

2018-534206 discloses an evaporative loss treatment system of an LNG carrier that includes a compression unit and a backup compression unit for alternate use when the primary compression unit cannot be used. Similarly to Japanese Laid-Open Patent Application No. 2018-534206, the Published Japanese Patent Application No. 2019-11735 discloses that two gas compressors are installed in parallel on an LNG carrier, one of which acts as a backup.

[0004]

When supplying gas from the evaporative loss compressor disclosed in Japanese Laid-Open Patent Application No. 2018-518415 to the demand destination, the total gas processing quantity (gas supply quantity) of the corresponding compressors installed in parallel must satisfy the gas demand quantity of the demand destination. Here, if the demand quantity of the demand destination fluctuates, the total gas supply quantity from the compressors does not coincide with the gas demand quantity, and as a result, the discharge pressure of each compressor fluctuates. Specifically, when the gas demand quantity increases, the discharge pressure decreases, while when the gas demand quantity decreases, the discharge pressure increases.

[0005]

Instead, by controlling each compressor so that the discharge pressure is maintained at a predetermined set pressure, it is assumed that the amount of gas supply from the compressor coincides with the changed amount of gas demand. However, if the set values (target values) of the discharge pressure of the respective compressors are the same, it is necessary to adjust the gas processing amount of both compressors based on the pressure information on the discharge side (demand side), leading to complex control. That is, if the accuracy of the pressure control is reduced, it may be difficult to match the gas supply quantity from the compressor with the gas demand quantity of the demand destination.

Summary of the invention

[0006]

An object of the present invention is to provide a compressor unit and a compressor unit control program which can easily match the gas supply quantity from the compressor with the gas demand quantity of the demand destination.

[0007]

A compressor unit according to one aspect of the present invention is a compressor unit installed on a ship and configured to compress a target gas which is an evaporation loss gas drawn from an LNG storage tank of the ship. The compressor unit includes a first reciprocating compressor, a second reciprocating compressor, and a control unit. The first reciprocating compressor includes a plurality of compression stages and compresses and delivers the target gas to the demand destination. The second reciprocating compressor includes a plurality of compression stages and is connected in parallel with the first reciprocating compressor to compress and deliver the target gas to the demand destination. The control unit is configured to control the movement of the first reciprocating compressor and the second reciprocating compressor. The first reciprocating compressor includes a first non-return valve provided downstream of the final compression stage, a first pressure sensor provided between the final compression stage and the first non-return valve, a first bypass flow channel which bypasses at least the final compression stage, and a first bypass valve provided in the first bypass flow channel; The second reciprocating compressor includes a second check valve provided downstream of the final compression stage, a second pressure sensor provided between the final compression stage and the second check valve, a second bypass flow channel which bypasses at least the final compression stage, and a second bypass valve provided in the second bypass flow channel; The compressor unit is configured so that the target gas discharged from the second reciprocating compressor and the target gas discharged from the first reciprocating compressor merge into a flow channel downstream of the first non-return valve and the second non-return valve. The control unit includes an opening degree control unit configured to control the opening degree of the first bypass valve and force the detection pressure of the first detection sensor to equal a first set value and control the opening degree of the second bypass valve and force the sensing pressure of the second sensing sensor to be equal to a second set value lower than the first set value.

[0008]

A compressor unit control program according to another aspect of the present invention is a program stored in a storage medium of a computer which controls the operation of the compressor unit and causes the computer comprising the control unit to act as the opening degree control unit or which controls the degree of opening of the first bypass valve and forces the detection pressure of the first pressure sensor to equal the first set value, while controlling the degree of opening of the second bypass valve and forces the detection pressure of the second pressure sensor to equal the second value adjustment.

Brief description of the blueprints

[0009]

Fig. 1 is a schematic diagram of a compressor unit according to embodiments,

Fig. 2 is a functional block diagram of a control unit in a first embodiment,

Fig. 3 is a flow chart for describing the degree of opening control of a first bypass valve;

Fig. 4 is a flow chart for describing the degree of opening control of a second bypass valve, and

Fig. 5 is a functional block diagram of a control unit in a second embodiment.

Description of implementations

[0010]

(First implementation)

A compressor unit and a compressor unit control program according to one embodiment will be described in detail below with reference to the drawings. Fig. 1 is a schematic diagram of a compressor unit 100.

The compressor unit 100 is installed on a ship (not shown) which includes a liquefied natural gas (LNG) storage tank 101 in which an LNG gas is stored. The compressor unit 100 is configured to suck in a target gas, which is an evaporation loss gas generated in the LNG storage tank 101 and compress the sucked target gas. Further, the compressor unit 100 is configured to provide the compressed target gas to a demand destination 501 (for example, an engine). In the following description, the terms "upstream" and "downstream" are used based on the direction of flow of the target gas.

[0012]

The compressor unit 100 includes a first reciprocating compressor 300, a second reciprocating compressor 400, and a control unit 420. The first reciprocating compressor 300 compresses and supplies the target gas to the demand destination 501. The second reciprocating compressor 400 is connected in parallel with the first reciprocating compressor. compressor 300 to compress and supply the target gas to the demand destination 501. The control unit 420 controls the movement of the first reciprocating compressor 300 and the second reciprocating compressor 400. The first reciprocating compressor 300 and the second reciprocating compressor 400 have in basic lines the same construction.

[0013]

The compressor unit 100 includes a flow channel 102 which forces the target gas, which is an evaporation loss gas generated in the LNG storage tank 101, to flow to the demand destination 501. The flow channel 102 interconnects the storage tank LNG 101 and the demand destination 501 to allow the target gas to be supplied to the demand destination 501. The flow channel 102 includes a first flow channel 110 which forces the target gas to flow through the first reciprocating compressor 300 and a second flow channel 210 which is connected to the first flow channel 110 and forces the target gas to flow through the second reciprocating compressor 400. The second flow channel 210 branches off from the first flow channel 110 in an area between the LNG storage tank 101 and the first compression stage 201 described below in the first flow channel 110. The second flow channel 210 is also connected to the first flow channel 110 downstream of the sixth compression stage 206 described later (final compression stage).

[0014]

The first reciprocating compressor 300 includes the first compression stage 201 to the sixth compression stage 206 which sequentially increase the pressure of the target gas, a plurality of coolers 281 to 285 and a drive unit (not shown). The drive unit includes a drive source (electric motor, motor or other similar machine) and a crank mechanism which transmits the power of the drive source to the first compression stage 201 to the sixth compression stage 206.

[0015]

The first two compression stages 201 are provided in the first flow channel 110. The second compression stage 202 through the sixth compression stage 206 are provided on a one-to-one basis in the first flow channel 110. Note that the embodiment is not limited to a configuration in which the two first compression stages 201 are provided in parallel with each other. The embodiment may have a configuration in which a first compression stage 201 is provided.

[0016]

The first flow channel 110 includes a storage tank connection flow channel 111 , a plurality of stage connection flow channels 115 to 119 , and a demand destination supply flow channel 114 .

[0017]

The storage tank connection flow channel 111 includes an upstream end connected to the LNG storage tank 101 and a downstream end connected to the first compression stage 201 of the compressor unit 100. More specifically, the storage tank connection flow channel 111 includes a main pipe 121 and pipes branch pipes 122 and 123. The main pipe 121 extends from an upper portion of the LNG storage tank 101. The branch pipes 122 and 123 are bifurcated at the downstream end of the main pipe 121 and are connected to the first two compression stages 201. That is, the first two compression stages 201 are connected to the storage tank connection flow channel 111 so as to be parallel to each other.

[0018]

The connecting flow channels of stages 115 to 119 are interconnected by pipes to allow the target gas to flow from one compression stage to the next compression stage. The stage connection flow channel 115 is configured to allow the target gas to flow from the first two compression stages 201 to the second compression stage 202. That is, the stage connection flow channel 115 includes a main pipe 124 and branch pipes 125 and 126. The main pipe 124 extends from the second compression stage 202 to the first compression stage 201. Branch pipes 125 and 126 are bifurcated at the upstream end of the main pipe 124 and connect to the first two compression stages 201. The stage connection flow channel 116 connects between them the second compression stage 202 and the third compression stage 203. The stage connection flow channel 117 connects together the third compression stage 203 and the fourth compression stage 204. The stage connection flow channel 118 connects together the fourth compression stage 204 and the fifth compression stage 205. The stage connection flow channel 119 interconnects the fifth compression stage 205 and the kth compression stage 206.

[0019]

The demand destination supply stream channel 114 is a stream channel that connects the sixth compression stage 206 to the demand destination 501 .

[0020]

The coolers 281 to 285 are configured to exchange heat between the target gas and cooling water having a lower temperature than the target gas. The cooler 281 is provided in the stage connection flow channel 116 for cooling the target gas discharged from the second compression stage 202. The cooler 282 is provided in the stage connection flow channel 117 for cooling the target gas discharged from the third compression stage 203. Cooler 283 is provided in the stage connection flow channel 118 for cooling the target gas discharged from the fourth compression stage 204. Cooler 284 is provided in the stage connection flow channel 119 for cooling the target gas discharged from the fifth compression stage 205. Cooler 285 is provided in the demand destination supply flow channel 114 to cool the target gas discharged from the sixth compression stage 206 .

[0021]

The compressor unit 100 (first reciprocating compressor 300) includes bypass flow channels 411 to 413 and 414A for adjusting the pressure of the target gas in the first flow channel 110. The bypass flow channels 411 to 413 are configured to return at least a portion of the target gas upstream from the branch parts 311 to 313 in the stage connection flow channels 116, 117 and 119, respectively. Branch parts 311 to 313 are located downstream of coolers 281, 282 and 284, respectively.

[0022]

The bypass flow channel 411 is connected to the main pipe 121 of the storage tank connection flow channel 111 by bypassing the first compression stage 201 and the second compression stage 202. The bypass flow channel 412 is connected to the stage connection flow channel 116 at a connection part 315 downstream of the branch part 311 and upstream of the third compression stage 203 when bypassing the third compression stage 203. The bypass flow channel 413 is connected to the stage connection flow channel 117 downstream of the branch part 312 and upstream of the fourth compression stage 204 when bypassing of the fourth compression stage 204 and the fifth compression stage 205. Bypass flow channel 414A (first bypass flow channel) is configured to return at least a portion of the target gas to the upstream side from a branch portion 314 of the demand destination supply flow channel 114 that located downstream of cooler 285.

That is, the bypass flow channel 414A is the first bypass flow channel which bypasses at least the final compression stage. The bypass flow channel 414A is connected to the stage connection flow channel 119 downstream of the branch section 313 and upstream of the sixth compression stage 206 when bypassing the sixth compression stage 206 (final compression stage).

[0023]

Bypass valves 421A, 422A, 423A and 424A are attached to bypass flow channels 411 through 413 and 414A, respectively. The bypass valve 424A provided in the bypass flow channel 414A corresponds to a first bypass valve provided in the first bypass flow channel which bypasses at least the final compression stage.

[0024]

Pressure sensors 431 to 433 and 434A are located in the first flow channel 110 and correspond to bypass flow channels 411 to 413 and 414A, respectively. The pressure sensor 431 is attached to the stage connection flow channel 116 downstream of the cooler 281 and upstream of the branch section 311 to detect the discharge pressure which is the pressure of the gas discharged from the second compression stage 202. The pressure sensor 432 is attached in the stage connection flow channel 117 downstream of the cooler 282 and upstream of the branch section 312 to detect the discharge pressure which is the pressure of the gas discharged from the third compression stage 203. The pressure sensor 433 is attached to the stage connection flow channel 119 downstream of the cooler 284 and upstream of the branch section 313 for sensing the discharge pressure which is the pressure of the gas discharged from the fifth compression stage 205. The pressure sensor 434A (first pressure sensor) is attached to the demand destination supply flow channel 114 downstream of the cooler 285 and downstream of the branch section 314 to detect of the discharge pressure which is the pressure of the gas discharged from the sixth compression stage 206 and is used to control the demand destination supply pressure.

[0025]

A first check valve 451 is provided downstream of the sixth compression stage 206 in the first flow channel 110. Specifically, the first check valve 451 is provided downstream of the branch portion 314 in the demand destination supply flow channel 114. The first check valve 451 prevents the backflow of gas. target from the demand destination side 501 to the side of the sixth compression stage 206 and the reverse flow from the second reciprocating compressor 400.

[0026]

In the following description, apart from the demand destination supply flow channel 114, an area upstream of the first check valve 451 (region on the side of the first reciprocating compressor 300) is referred to as "first compressor side flow channel portion 114A". Outside of the demand destination supply flow channel 114, an area downstream of the first check valve 451 is referred to as "demand side flow channel first portion 114D". Outside of the demand destination supply flow channel 114 in the second flow channel 210, an area upstream of the second check valve 452 described later (second reciprocating compressor side area 400) is referred to as "second compressor side flow channel portion 114B". Outside of the demand destination supply flow channel 114 in the second flow channel 210, an area downstream of the second check valve 452 is referred to as "second demand side flow channel portion 114C". The second demand side flow channel section 114C is connected to the first demand side flow channel section 114D. The pressure sensor 434A is provided between the branch section 314 and the first check valve 451 in the first compressor side flow channel section 114A.

[0027]

As shown in Fig. 1, the upstream end of the second flow channel 210 is connected to the main pipe 121 of the flow channel connecting the storage tank 111 to the first flow channel 110. Meanwhile, the downstream end of the second flow channel 210 is connected to the flow channel demand destination delivery 114 to the first flow channel 110. That is, the target gas discharged from the second reciprocating compressor 400 through the second demand side flow channel section 114C and the target gas discharged from the first reciprocating compressor 300 through the first side channel section demand flow 114D merge into a junction 13.

[0028]

The second reciprocating compressor 400 is similar in configuration to the first reciprocating compressor 300 (same number of compression stages). In Fig. 1, the corresponding configurations between the second reciprocating compressor 400 and the first reciprocating compressor 300 are indicated in outline with the same reference numerals. That is, the second reciprocating compressor 400 includes the first to sixth compression stages 201 to 206. A bypass flow channel 411 which bypasses the first compression stage 201 and the second compression stage 202 is provided, a bypass flow channel 412 which bypasses the third compression stage 203 and a bypass flow channel 413 which bypasses the fourth compression stage 204 and the fifth compression stage 205. Bypass valves 421B, 422B and 423B are attached to the bypass flow channels 411 to 413, respectively. In addition, a second bypass flow channel 414B is provided which bypasses the sixth compression stage 206. A second bypass valve 424B is attached to the second bypass flow channel 414B. The second bypass flow channel 414B is a bypass flow channel which bypasses at least the final compression stage.

[0029]

In addition, the second reciprocating compressor 400 includes the second check valve 452 and a second pressure sensor 434B provided downstream of the sixth compression stage 206. The second check valve 452 is provided downstream of the branch section 314 in the demand destination supply flow channel 114 in the second flow channel 210 and prevents the reverse flow of the target gas from the first reciprocating compressor side 300. The second pressure sensor 434B is provided between the sixth compression stage 206 and the second check valve 452, i.e., in the second compressor side flow channel section 114B in the second channel flow 210.

[0030]

In the compressor unit 100, the first reciprocating compressor 300 and the second reciprocating compressor 400 are basically of the same construction, making it possible to standardize the parts used in each compressor.

[0031]

As shown in Fig. 2 , the control unit 420 includes a pressure detection receiving unit 461 , a determination unit 463 , an opening degree control unit 464 , and a storage unit 466 .

[0032]

The pressure detection receiving unit 461 receives the data indicating the detection pressure of the first pressure sensor 434A and the detection pressure of the second pressure sensor 434B.

[0033]

The adjustment value of the discharge pressure in the sixth compression stage 206 of the second reciprocating compressor 400 (hereinafter referred to as “second adjustment value”) is lower than the adjustment value of the discharge pressure in the sixth compression stage 206 of the first reciprocating compressor 300 (hereinafter in herein referred to as “first setting value"). The first setting value is set equal to the required pressure of the demand destination 501. In the present embodiment, the second setting value is 99% or greater and less than 100% of the first setting value. In the following description, it is assumed that the first setting value is 30 MPa and the second setting value is 29.9 MPa.Note that the second setting value may be another value equal to or greater than 29.7 MPa and less than 30 MPa.

[0034]

The determination unit 463 compares the detection pressure from the first pressure sensor 434A with the first setting value to determine the magnitude relationship between them. The determination unit 463 also compares the sensed pressure from the second pressure sensor 434B with the second setting value to determine the magnitude relationship between them. The determination unit 463 outputs the information for each determination result to the aperture degree control unit 464.

[0035]

The opening degree control unit 464 controls the opening degree of the first bypass valve 424A so that the detection pressure of the first pressure sensor 434A becomes the first set value. The opening degree control unit 464 also controls the opening degree of the second bypass valve 424B so that the detection pressure of the second pressure sensor 434B becomes the second set value. The opening degree control unit 464 transmits an opening degree change signal (opening degree increase signal or opening degree decrease signal) to the first bypass valve 424A and the second bypass valve 424B based on the determination result information output from the determination unit 463 .Details of this control will be described later.

[0036]

The storage unit 466 stores a program for controlling the operation of the compressor unit 100. The compressor unit control program causes a computer constituting the control unit 420 to act as the pressure sensing acquisition unit 461, the determination unit 463, and the degree control unit opening 464. That is, the computer (central processing unit or CPU) constituting the control unit 420 reads and executes the program stored in the storage unit 466, thereby implementing the functions of the pressure detection receiving unit 461, the determining unit 463 and the opening degree control unit 464. The storage unit 466 includes a storage medium such as various memory devices, and the compressor unit control program is stored in the storage medium.

[0037]

With the same operational configuration as described above, the control unit 420 can also control the opening degree of the bypass valve 421A based on the detection pressure of the pressure sensor 431 of the first reciprocating compressor 300. Similarly, the control unit 420 can control the degree opening the bypass valves 422A and 423A based on the sensed pressure of the pressure sensors 432 and 433, respectively. Bypass valves 421B to 423B of the second reciprocating compressor 400 may be controlled in a similar manner.

[0038]

Note that control unit 420 may include a plurality of controllers provided in correspondence with bypass valves 421A through 424A and 421B through 424B. In this case, the respective controllers have functions corresponding to the pressure detection receiving unit 461 , the determination unit 463 , the opening degree control unit 464 , and the storage unit 466 .

[0039]

The control of the degree of opening of the first bypass valve 424A and the second bypass valve 424B performed by the degree of opening control unit 464 will be described below with reference to the flow charts of Figs. 3 and 4. Fig. 3 is a flow chart for the description of controlling the degree of opening of the first bypass valve 424A. Fig. 4 is a flow chart for describing the control of the degree of opening of the second bypass valve 424B.

[0040]

First, it will describe the control of the degree of opening of the first bypass valve 424A with reference to Fig. 3. First, the first pressure sensor 434A detects the gas pressure in the first compressor side flow channel section 114A and transmits the data indicating the detection pressure in the pressure detection receiving unit 461 (step S10). Next, the determination unit 463 compares the detection pressure of the first pressure sensor 434A (hereinafter also referred to as the first detection pressure) with the first setting value and determines whether the first detection pressure is greater than the first setting value (step S20).

[0041]

When the first detection pressure is greater than the first setting value (YES in step S20), the opening degree control unit 464 receives information of the determination result from the determination unit 463 and increases the opening degree of the first bypass valve 424A (step S30 ). This increases the flow of target gas flowing from the bypass section 314 to the first bypass flow channel 414A, while gradually decreasing the pressure sensed in the first compressor side flow channel section 114A. On the other hand, when the first detection pressure is equal to or less than the first setting value (NO in step S20), the opening degree control unit 464 does not increase the opening degree of the first bypass valve 424A, and the process continues to step S40.

[0042]

In step S40, the determination unit 463 compares the first detection pressure with the first setting value to determine whether the first detection pressure is less than the first setting value. When the first detection pressure is less than the first setting value (YES in step S40), the opening degree control unit 464 receives determination result information from the determination unit 463 and decreases the opening degree of the first bypass valve 424A (step S50) . This reduces the flow of target gas flowing from the bypass section 314 to the first bypass flow channel 414A, while gradually increasing the pressure sensed in the first compressor side flow channel section 114A. On the other hand, when the first detection pressure is equal to the first setting value (NO in step S40), the opening degree control unit 464 does not increase or decrease the opening degree of the first bypass valve 424A, and the process returns to step S10. Repeating the above steps S 10 to S50 , the first detection pressure detected in the first compressor side flow channel portion 114 A approaches the first setting value (for example, 30 MPa).

[0043]

Fig. 4 is a flow diagram showing the flow of the degree of opening control of the second bypass valve 424B. This control flow is the same as the control flow of Fig. 3 except that the second pressure sensor 434B is used instead of the first pressure sensor 434A, the second set value is used instead of the first set value, and the degree of opening of the second bypass valve 424B is controlled instead of of the first bypass valve 424A. Therefore, the detailed description of the control flow of the second bypass valve 424B will be omitted. By repeating steps S11 to S51 in Fig. 4 , the pressure detected by the second pressure sensor 434B in the second compressor side flow channel portion 114B approaches the second set value (for example, 29.9 MPa).

[0044]

As described above, while the second reciprocating compressor 400 is controlled so that the target gas pressure in the second compressor side flow channel portion 114B becomes the second set value, the first reciprocating compressor 300 is controlled so that the target gas pressure in the first side flow channel portion compressor 114A to become the first setting value.

[0045]

In the compressor unit 100, when the pressure of the target gas in the first compressor side flow channel section 114A and the second compressor side flow channel section 114B is greater than the pressure of the target gas in the first demand side flow channel section 114D and the second flow channel section demand side 114C, target gas is supplied to demand destination 501 from each of compressors 300 and 400.

[0046]

As described above, the first discharge pressure adjustment value of the first reciprocating compressor 300 is greater than the second discharge pressure adjustment value of the second reciprocating compressor 400. Accordingly, the opening degree of the first bypass valve 424A of the first reciprocating compressor 300 is less than the opening degree of the second bypass valve 424B of the second reciprocating compressor 400. As a result, the amount of target gas supplied from the first reciprocating compressor 300 to the demand destination 501 is greater than the amount supplied from the second reciprocating compressor 400.

[0047]

Meanwhile, when the gas demand amount from the demand destination 501 is reduced, the consumption of the target gas is reduced and thus the pressure in the first demand side flow channel section 114D and the second demand side flow channel section 114C is increased. Then, when the pressure exceeds the second setting value, the second reciprocating compressor 400 does not send the target gas to the downstream side of the second check valve 452. Therefore, the target gas is supplied to the demand destination 501 only by the first reciprocating compressor 300.

[0048]

In this way, by setting the second setting value smaller than the first setting value, the target gas can be supplied to the demand destination 501 in an amount proportional to the required amount of the demand destination 501 without performing control to adjust the supply balance between and of the two compressors 300 and 400 whenever the gas demand quantity of the demand destination 501 changes.

[0049]

With this connection, a device of the demand destination 501 may disconnect the load due to a sudden shutdown or other similar cause. In this case, to prevent the flow of the entire amount of target gas discharged from both compressors 300 and 400 to the second demand side flow channel section 114C, the control unit 420 forcibly increases the degree of opening of the bypass valves 421A to 424A and 421B to 424B of all compression stages 201 to 206. In this case, since the amount of target gas discharged from the first reciprocating compressor 300 is greater than the amount of target gas discharged from the second reciprocating compressor 400, the increase in the degree of opening of the bypass valves 421A to 424A in the first reciprocating compressor 300 is greater than the increase in the degree of opening of the bypass valves 421B to 424B in the second reciprocating compressor 400. This may prevent the supply of the target gas to the demand destination 501 in a situation where the load is cut off from both compressors 30 0 and 400. It should be noted that the increase in the degree of opening of bypass valves 421A to 424A and 421B to 424B can be corrected taking into account the characteristics of each bypass valve.

[0050]

The first embodiment of the present invention has been described above. As a comparative example for the first embodiment when the two reciprocating compressors 300 and 400 are to be operated simultaneously, the discharge pressure control is considered in which the discharge pressure setting values in the final compression stage of the two compressors are the same. However, in such a discharge pressure control, since it is necessary to control that the opening degrees of the first and second bypass valves 424A and 424B are always the same when the pressure of the demand destination 501 is changed, it is necessary to change the opening degrees of both bypass valves by the same percentage according to the change. Therefore, the control of the discharge pressure of the compressor unit 100 becomes complex.

[0051]

In contrast, in the compressor unit 100 according to the present embodiment, a difference is set in the discharge pressure setting value of the sixth compression stage 206, that is, the final compression stage. Accordingly, if the gas demand amount of the demand destination 501 is changed, a state in which the target gas is supplied by both compressors 300 and 400 is changed to a state in which the target gas is supplied only by the first reciprocating compressor 300. That is, the target gas in the amount equal to the demand amount of the demand destination 501 can be supplied to the demand destination 501 without performing the discharge pressure control according to the comparative example.

(Second implementation)

Next, it will describe a compressor unit and a compressor unit control program according to a second embodiment with reference to Fig. 5. Note that since the second embodiment is broadly similar to the first embodiment, only the differences from the first embodiment will be described herein.

[0053]

As shown in Fig. 5, a control unit 420 in the second embodiment further includes a set value determination unit 462 and a required pressure receiving unit 465. The required pressure receiving unit 465 receives data indicating the required pressure of the target gas from a demand destination 501. The set value determination unit 462 determines a first set value and a second set value based on the required pressure of the target gas obtained from the required pressure receiving unit 465. For example, when the required pressure of the demand destination 501 is 30 MPa , the setting value determining unit 462 sets the first setting value equal to 30 MPa, which is the same as the required pressure, and sets the second setting value equal to the value 29.7 MPa or more and less than 30 MPa.

[0054]

Based on the change in the required pressure from the demand destination 501, the set value determination unit 462 changes the first set value and the second set value while maintaining the difference between the first set value and the second set value. For example, when the required pressure changes from 30 MPa to 25 MPa, data indicating the changed required pressure is input from the demand destination 501 to the required pressure receiving unit 465. Based on this input data, the set value determination unit 462 changes the first setting value from 30 MPa to 25 MPa, while changing the second setting value to a value greater than or equal to 24.75 MPa and less than 25 MPa.

[0055]

The compressor unit control program according to the second embodiment causes a computer constituting the control unit 420 to function as a set value determination unit 462 as well as a required pressure acquisition unit 465. That is, by reading and executing the program stored in a unit storage 466 by a CPU, it is possible to obtain the functions of the set value determination unit 462 and the required pressure acquisition unit 465.

[0056]

As described above, in the second embodiment, when the first setting value and the second setting value change in response to the change in the required pressure of the demand destination 501, the difference between the two setting values is maintained. Even in this case, it is possible to implement the operation of a compressor which can easily cover the gas demand amount of the demand destination 501.

[0057]

(Third implementation)

Next, it will describe a compressor unit 100 according to a third embodiment. A second setting value of a second reciprocating compressor 400 may be a value equal to or greater than 93% (28 MPa) and less than 99% (29.7 MPa) of a first setting value of a first reciprocating compressor 300. In this case, while the compressor unit 100 is in operation, the target gas is not normally supplied from the second reciprocating compressor 400 to a demand destination 501 , while the target gas is supplied to the demand destination 501 only from the first reciprocating compressor 300 .

[0058]

Meanwhile, when the gas demand amount from the demand destination 501 increases and the increased demand amount exceeds the maximum gas processing amount (maximum gas supply amount) of the first reciprocating compressor 300, even if a first bypass valve 424A is fully closed, the gas supply quantity to demand destination 501 is insufficient. As a result, the amount of the target gas is reduced in a first demand side flow channel section 114D and a second demand side flow channel section 114C, while the pressure is gradually reduced.

[0059]

Then, when the pressure of the first demand side flow channel section 114D and the second demand side flow channel section 114C is reduced to the second set value, the target gas compressed by the second reciprocating compressor 400 flows from an inlet 13 to the first side flow channel section demand stream 114D and supplied to the demand destination 501. In this way, it is possible to make up for the lack of the gas treatment amount from the first reciprocating compressor 300 by the gas treatment amount of the second reciprocating compressor 400, while it is possible to cover the increased amount gas demand from demand destination 501.

[0060]

The embodiments disclosed herein should be considered in all respects as illustrative and not restrictive. The subject matter of the present invention is indicated by the appended claims rather than by the preceding description, and all changes which fall within the meaning and scope of the claims and their equivalents are therefore intended to be embraced therein. Therefore, the following aspects are also included in the scope of the present invention.

[0061]

The above embodiments described a case in which the target gas pressure is controlled using the bypass mechanism (bypass flow channel and bypass valve), but the embodiment is not limited to this example. As a control of the processing amount and pressure of the target gas, in addition to the control using the bypass mechanism, for example, it is possible to further combine a known control such as an unloader control.

[0062]

The above embodiments described a case in which both the first reciprocating compressor 300 and the second reciprocating compressor 400 have six compression stages, but the number of compression stages may be 5 or less or 7 or more. In addition, the number of compression stages of the first reciprocating compressor 300 may differ from the number of compression stages of the second reciprocating compressor 400.

[0063]

The demand destination 501 is not limited to an engine, but may be other marine equipment such as a generator.

[0064]

In the above embodiments, the bypass flow channel 414A (or the first bypass flow channel) only bypasses the final compression stage, but instead of this example, the bypass flow channel 414A may bypass the final compression stage and one or more compression stages prior to final compression stage. The second bypass flow channel 414B only bypasses the final compression stage, but instead of this example, the second bypass flow channel 414B may bypass the final compression stage and one or more compression stages before the final compression stage.

[0065]

Here, the above implementations will be generally described.

[0066]

(1) A compressor unit according to the above embodiments is a compressor unit installed on a ship and configured to compress a target gas which is an evaporation loss gas drawn from an LNG storage tank of the ship. The compressor unit includes a first reciprocating compressor, a second reciprocating compressor, and a control unit. The first reciprocating compressor includes a plurality of compression stages and compresses and delivers the target gas to the demand destination. The second reciprocating compressor comprises a plurality of compression stages and is connected in parallel with the first reciprocating compressor to compress and deliver the target gas to the demand destination. The control unit is configured to control the operation of the first reciprocating compressor and the second reciprocating compressor. The first reciprocating compressor includes a first non-return valve provided downstream of a final compression stage, a first pressure sensor provided between the final compression stage and the first non-return valve, a first bypass flow channel which bypasses at least the final compression stage, and a first bypass valve provided in the first bypass flow channel; The second reciprocating compressor includes a second check valve provided downstream of a final compression stage, a second pressure sensor provided between the final compression stage and the second check valve, a second bypass flow channel which bypasses at least the final compression stage, and a second bypass valve provided in the second bypass flow channel; The compressor unit is configured so that the target gas discharged from the second reciprocating compressor and the target gas discharged from the first reciprocating compressor merge into a flow channel downstream of the first non-return valve and the second non-return valve. The control unit includes an opening degree control unit configured to control the opening degree of the first bypass valve and to force the equation of the detection pressure of the first pressure sensor with a first set value and to control the opening degree of the second bypass valve and to force equating the sensed pressure of the second pressure sensor to a second set value less than the first set value.

[0067]

In this compressor unit, the discharge pressure of the first reciprocating compressor is controlled at the first setting value, while the discharge pressure of the second reciprocating compressor is controlled at the second setting value which is less than the first setting value. When the two reciprocating compressors are to be operated simultaneously, as a comparative example of the present invention, it would be possible to consider the discharge pressure control in which the discharge pressure setting values in the final compression stages of the compressors are the same. However, in such a discharge pressure control, since it is necessary to control that the opening degrees of the first and second bypass valves are always the same, when the pressure of the demand destination is changed, it is necessary to change the opening degrees of both bypass valves by the same percentage according to the change. Therefore, the control of the discharge pressure of the compressor unit becomes complex. In contrast, in the above embodiments, a difference is defined in the discharge pressure setting values of the final compression stages. Accordingly, if the gas demand quantity of the demand destination is changed, a state in which the target gas is supplied by both compressors is changed to a state in which the target gas is supplied only by the first reciprocating compressor. That is, the target gas in the amount equal to the demand amount of the demand destination can be easily supplied to the demand destination without performing the discharge pressure control according to the comparative example.

[0068]

(2) In the above compressor unit, the second setting value may be a value equal to or greater than 99% and less than 100% of the first setting value.

[0069]

With this configuration, since the second setting value is slightly smaller than the first setting value, when the gas supply amount from the first reciprocating compressor is insufficient, the discharge pressure of the first reciprocating compressor immediately reaches the second setting value. Accordingly, when the gas supply amount from the first reciprocating compressor is insufficient, the gas supply from the second reciprocating compressor to the demand destination can be started immediately.

[0070]

(3) In the above compressor unit, the control unit may further include: a required pressure receiving unit configured to receive the required pressure of the target gas from the demand destination and a setting value determining unit configured to determine the first setting value and the second set value based on the required pressure obtained from the required pressure receiving unit. The set value determining unit may change the first set value and the second set value while maintaining a difference between the first set value and the second set value based on a change in required pressure.

[0071]

With this configuration, when the first set value and the second set value are changed in response to the change in the required pressure of the demand destination, maintaining the difference between the two set values as before the set value change, the gas supply from the second reciprocating compressor can be started immediately when the amount of gas supply from the first reciprocating compressor is insufficient.

[0072]

(4) In the above compressor unit, the first reciprocating compressor and the second reciprocating compressor may include an equal number of compression stages.

[0073]

(5) In the above compressor unit, the control unit may be configured to: forcibly increase the opening degree of the first bypass valve to force the return of the total amount of the target gas discharged from the first reciprocating compressor from a downstream flow channel of the final compression stage of the first reciprocating compressor and forcefully increase the degree of opening of the second bypass valve to force the return of the total amount of target gas discharged from the second reciprocating compressor through a flow channel downstream of the final compression stage of the second reciprocating compressor compressor, when the demand destination cuts off a load, where an increase in the degree of opening of the first bypass valve may be greater than that of the second bypass valve.

With this configuration, it is possible to prevent the target gas from being supplied to the demand destination in a state in which the load is cut off from the first and second reciprocating compressors.

[0075]

(6) A compressor unit control program according to the above embodiments is a program stored in a storage medium of a computer and which controls the operation of the compressor unit to force the computer constituting the control unit to operate as an opening degree control unit or which controls the degree of opening of the first bypass valve to cause the detection pressure of the first pressure sensor to equal the first set value and controls the degree of opening of the second bypass valve to cause the detection pressure of the second pressure sensor to equal the second setting value.

[0076]

By running the computer with this program, the target gas is normally supplied to the demand destination only from the first reciprocating compressor. Therefore, unlike the case in which gas is continuously supplied from the two compressors to the demand destination, it is possible to prevent the pressure control accuracy from decreasing.

[0077]

As is evident from the above description, the gas supply quantity from the compressors can easily be matched with the gas demand quantity of the demand destination.

[0078]

This application is based on Japanese Patent Application No. 2021-851 filed Jan. 6, 2021, the contents of which are incorporated herein by reference.

[0079]

Although the present invention has been fully described by way of example with reference to the accompanying drawings, it should be understood that various changes and modifications will become apparent to those skilled in the art. Accordingly, unless such changes and modifications otherwise depart from the scope of the present invention as defined hereinbelow, they should be deemed to be included therein.

Claims (6)

Claims 1. A compressor unit which is installed inside a ship to compress a target gas which is an evaporation loss gas drawn from an LNG storage tank of the ship, the compressor unit comprising: a first reciprocating compressor comprising a plurality of compression stages and configured to compress and deliver the target gas to a demand destination, a second reciprocating compressor comprising a plurality of compression stages and connected in parallel to the first reciprocating compressor to compress and deliver of the target gas at the demand destination, and a control unit configured to control the operation of the first reciprocating compressor and the second reciprocating compressor; wherein the first reciprocating compressor comprises: a first check valve provided downstream of a final compression stage, a first pressure sensor provided between the final compression stage and the first check valve; a first bypass flow channel which bypasses at least the final compression stage, and a first bypass valve provided in the first bypass flow channel, the second reciprocating compressor includes; a second check valve provided downstream of a final compression stage; a second pressure sensor provided between the final compression stage and the second check valve; a second bypass flow channel which bypasses at least the final compression stage, and a second bypass valve provided in the second bypass flow channel, the compressor unit configured to cause the target gas discharged from the second reciprocating compressor and the target gas discharged from the first reciprocating compressor to merge in a flow channel downstream of the first non-return valve and the second non-return valve, the control unit includes an opening degree control unit configured to control the opening degree of the first bypass valve and force the detection pressure of the first pressure sensor to equal a first set value and control the opening degree of the second bypass valve and force the detection pressure of the second pressure sensor to be equal to a second set value less than the first set value. 2. The compressor unit according to claim 1, wherein the second setting value is a value equal to or greater than 99% and less than 100% of the first setting value. 3. The compressor unit according to claim 1 or 2, wherein the control unit further includes: a required pressure receiving unit configured to receive the required target gas pressure from the demand destination, and a setpoint value determination unit configured to determine the first setpoint value and the second setpoint value based on the required pressure received from the required pressure receiving unit; the setpoint determining unit changes the first setpoint value and the second setpoint value while maintaining a difference between the first setpoint value and the second setpoint value based on a change in required pressure. The compressor unit according to claim 1 or 2, wherein the first reciprocating compressor and the second reciprocating compressor comprise an equal number of compression stages. The compressor unit according to claim 1 or 2, wherein the control unit is configured to: forcibly increasing the degree of opening of the first bypass valve to force the return of the total amount of target gas discharged from the first reciprocating compressor through a flow channel downstream of the final compression stage of the first reciprocating compressor, and forcibly increasing the degree of opening of the second bypass valve to force the return of the total amount of the target gas discharged from the second reciprocating compressor from a flow channel downstream of the final compression stage of the second reciprocating compressor when the demand destination cuts off a load , where an increase in the degree of opening of the first bypass valve is greater than that of the second bypass valve. A program stored on a storage medium of a computer which controls the operation of the compressor unit according to claim 1 to cause the computer constituting the control unit to operate as an opening degree control unit which controls the opening degree of the first bypass valve and causes the detection pressure of the first pressure sensor to be equal to the first setting value and controls the degree to forces its detection pressure and second set value. the opening of the second bypass valve of the second pressure sensor to be equal to