JP6911457B2 - Compressed air supply system - Google Patents

Description

The present invention relates to a compressed air supply system.

Compressed air is used for various purposes in industrial facilities such as factories. The industrial facility is provided with a compressed air supply system that supplies compressed air. The compressed air supply system has an air compressor that produces compressed air at the feed point and supplies the generated compressed air to the point of use.

Special Publication No. 63-32990 Japanese Unexamined Patent Publication No. 2016-132149

When each of the plurality of feed points of compressed air and the plurality of use points of compressed air are distributed and installed, a technique capable of supplying the compressed air generated at the feed points to the use points at an appropriate pressure is required.

An aspect of the present invention is to provide a compressed air supply system capable of supplying compressed air to a point of use at an appropriate pressure.

According to an aspect of the present invention, a network pipeline connecting a plurality of feed points of compressed air and a plurality of use points of the compressed air, and a plurality of airs producing the compressed air at each of the plurality of feed points. The compression determined from the compressor group, a plurality of pressure sensors that detect the pressure of the compressed air at each of the plurality of detection positions set in the flow path of the compressed air, and the detection pressure values of the plurality of pressure sensors. A centralized control device for collectively and remotely controlling the operation of a plurality of the air compressor groups based on the representative pressure value of air is provided , and the representative pressure value is set in the network pipeline and the use point. It is an average value of the detected pressure values at a plurality of the detected positions, and the average value is a weighted average value weighted with the detected pressure values at the specific detection positions set for the specific use points among the use points. , A compressed air supply system is provided.

According to an aspect of the present invention, there is provided a compressed air supply system capable of supplying compressed air to a point of use at an appropriate pressure.

FIG. 1 is a diagram schematically showing an example of a compressed air supply system according to the first embodiment. FIG. 2 is a functional block diagram showing an example of the centralized control device and the local control device according to the first embodiment. FIG. 3 is a flowchart showing an example of the operation of the compressed air supply system according to the first embodiment. FIG. 4 is a flowchart showing an example of the operation of the compressed air supply system according to the second embodiment. FIG. 5 is a flowchart showing an example of the operation of the compressed air supply system according to the third embodiment. FIG. 6 is a diagram for explaining an example of the supply / demand area according to the fourth embodiment. FIG. 7 is a flowchart showing an example of the operation of the compressed air supply system according to the fourth embodiment. FIG. 8 is a diagram showing an example of a supply / demand area according to the fifth embodiment. FIG. 9 is a diagram for explaining an example of the pressure drop rate at the detection position of the supply / demand area according to the fifth embodiment. FIG. 10 is a flowchart showing an example of the operation of the compressed air supply system according to the fifth embodiment. FIG. 11 is a diagram schematically showing an example of a network pipeline. FIG. 12 is a diagram schematically showing an example of a network pipeline. FIG. 13 is a diagram schematically showing an example of a network pipeline.

Hereinafter, embodiments according to the present invention will be described with reference to the drawings, but the present invention is not limited thereto. The components of the embodiments described below can be combined as appropriate. In addition, some components may not be used.

First embodiment.
[Compressed air supply system]
FIG. 1 is a diagram schematically showing an example of a compressed air supply system 1 according to the present embodiment. The compressed air supply system 1 is provided in an industrial facility such as a factory. The compressed air supply system 1 includes a plurality of feed points 2 of compressed air, a plurality of use points 3 of compressed air, a network pipeline 4 connecting each of the plurality of feed points 2 and the plurality of use points 3, and a plurality of use points 3. Each of the feed points 2 includes a plurality of air compressor groups 5 that generate compressed air.

Further, the compressed air supply system 1 includes a plurality of pressure sensors 6 for detecting the pressure of compressed air at each of a plurality of detection positions set in the flow path of the compressed air, a communication system 7, and a plurality of air compressor groups 5. It is provided with a centralized control device 10 that collectively and remotely controls the operation of the above.

The feed point 2 has a compressed air supply facility that generates and supplies compressed air. Use point 3 has a compressed air use facility that uses compressed air. The plurality of feed points 2 are installed at locations separated from each other. The plurality of use points 3 are installed at locations separated from each other. Each of the plurality of feed points 2 and the plurality of use points 3 is distributedly installed in the industrial facility.

The network pipeline 4 is laid so as to connect each of the plurality of feed points 2 and the plurality of use points 3. In the present embodiment, the network pipeline 4 is a loop type pipeline. The network pipeline 4 has a loop-shaped main pipeline 40, a plurality of feed pipelines 8 branching from the main pipeline 40, and a plurality of youth pipelines 9 branching from the main pipeline 40. The feed line 8 is connected to the main line 40 at the connecting portion 8C. The youth pipeline 9 is connected to the main pipeline 40 at the connecting portion 9C.

The feed point 2 is connected to the feed line 8. The feed point 2 supplies compressed air to the network pipeline 4. The feed point 2 has an air compressor group 5 that generates compressed air and a local control device 30. The feed pipeline 8 is provided with a receiver tank 20 for temporarily storing compressed air sent from the air compressor group 5, and an on-off valve 21 for opening and closing the flow path of the feed pipeline 8.

The air compressor group 5 is composed of a plurality of air compressors 50. In the present embodiment, the air compressor group 5 is composed of three air compressors 50. The feed pipe line 8 has a connecting pipe line connected to each of the plurality of air compressors 50 and a collecting pipe line in which the plurality of connecting pipe lines are aggregated. The compressed air generated by each of the plurality of air compressors 50 is supplied to the main pipeline 40 via the feed pipeline 8.

The receiver tank 20 is provided in the collecting pipe of the feed pipe 8. The compressed air sent out from the air compressor group 5 is temporarily stored in the receiver tank 20. The receiver tank 20 suppresses abrupt pressure fluctuations in the compressed air sent from the feed point 2.

The youth point 3 is connected to the youth pipeline 9. The use point 3 uses compressed air supplied from the feed point 2 via the network pipeline 4. At least a part of the compressed air flowing through the main pipeline 40 is supplied to the use point 3 via the youth pipeline 9.

The equipment using compressed air of use point 3 includes, for example, an air gun or air spray that injects compressed air, an air actuator such as an air cylinder that is operated by compressed air, and a blow molding machine that molds parts using compressed air. Various compressed air use facilities that utilize air are exemplified. At use point 3, the product may be produced using the power of compressed air.

The pressure sensor 6 is provided at each of the plurality of detection positions set in the flow path of the compressed air. The pressure sensor 6 detects the pressure of the compressed air at the detection position. The detection position is set in at least a part of the network line 4 including the receiver tank 20 and the use point 3.

In the present embodiment, the pressure sensor 6 is a receiver tank pressure sensor 61 that detects the pressure of compressed air in the receiver tank 20 at a detection position set in the receiver tank 20, and a feed pipe at a detection position set in the feed pipeline 8. In the feed line pressure sensor 62 that detects the pressure of the compressed air in the path 8, the network line pressure sensor 63 that detects the pressure of the compressed air in the main line 40 at the detection position set in the main line 40, and the youth line 9. The youth line pressure sensor 64 that detects the compressed air pressure of the youth line 9 at the set detection position, and the use point pressure that detects the compressed air pressure of the use point 3 at the detection position set at the use point 3. Includes sensor 65.

The receiver tank pressure sensor 61 is provided in each of the plurality of receiver tanks 20 and detects the pressure of the compressed air of the plurality of receiver tanks 20. The feed pipe pressure sensor 62 is provided in each of the plurality of feed pipes 8 and detects the pressure of the compressed air in the plurality of feed pipes 8. The network line pressure sensor 63 is provided at each of the plurality of parts of the main line 40, and detects the pressure of the compressed air at the plurality of parts of the main line 40. The youth pipe pressure sensor 64 is provided in each of the plurality of youth pipes 9 and detects the pressure of the compressed air in the plurality of youth pipes 9. The use point pressure sensor 65 is provided at each of the plurality of use points 3, and detects the pressure of the compressed air of the plurality of use points 3.

In the following description, the value of the pressure of the compressed air detected by the pressure sensor 6 (61, 62, 63, 64, 65) is appropriately referred to as a detected pressure value Ps.

As the detected pressure value Ps of each pressure sensor 6, each of the time series data sampled in a predetermined cycle may be used as the detected pressure value Ps, but depending on the detection position of each pressure sensor 6, N samples sampled in a predetermined cycle. It is desirable to smooth the time-series data of the above and use the value calculated as the moving average value as the detected pressure value Ps. For example, in the receiver tank 20, which is also a buffer device for compressed air, the time change of the pressure sampling data according to the fluctuation of the amount of compressed air used is gradual. Therefore, the local pressure of the receiver tank 20 can be accurately represented without using the detected pressure value Ps of the receiver tank pressure sensor 61 as the moving average value. On the other hand, in the youth pipeline 9 and the use point 3, the pressure sampling data may change drastically with time according to the fluctuation of the amount of compressed air used. In such a case, by using the detected pressure value Ps of the youth line pressure sensor 64 and the use point pressure sensor 65 as the moving average value, the local pressure of the youth line 9 and the use point 3 can be accurately represented. can do.

When calculating the detected pressure value Ps as the moving average value, it is preferable to process the N time series data so that the abnormal data due to electrical noise or the like is not included. Specifically, an upper limit threshold value and a lower limit threshold value for removing abnormal data are set, and when the pressure sampling data is not within the range of the upper limit threshold value and the lower limit threshold value, the pressure sampling data is not adopted. By processing in this way, the local pressure can be detected more accurately.

Further, the compressed air supply system 1 includes a booster compressor 55 that boosts the compressed air supplied to a specific use point 3 among the plurality of use points 3. In the present embodiment, the booster compressor 55 is provided in the youth conduit 9 connected to the use point 3 of any one of the four use points 3. In the youth pipeline pressure sensor 64 and the use point pressure sensor 65 arranged on the downstream side of the booster compressor 55, the detected pressure value Ps is the value after boosting. Therefore, when the detection pressure value Ps of the specific pressure sensors 64 and 65 is acquired by the detection pressure acquisition unit 11 (described later), the value obtained by dividing by the amplification factor (ratio of the pre-boost pressure and the post-boost pressure) is the detection pressure. The value is Ps.

The centralized control device 10 and the local control device 30 wirelessly communicate with each other via the communication system 7. Further, the centralized control device 10 and the pressure sensor 6 wirelessly communicate with each other via the communication system 7.

The centralized control device 10 collectively remotely controls the operation of the plurality of air compressor groups 5 based on the pressure in the flow path of the compressed air. In the present embodiment, the centralized control device 10 collectively remotely controls the operation of the plurality of air compressor groups 5 based on the representative pressure value Pm of the compressed air determined from the detected pressure values Ps of the plurality of pressure sensors 6. do. The centralized control device 10 transmits a command signal to the local control device 30 via the communication system 7 to remotely control the air compressor group 5.

[Centralized control device and local control device]
FIG. 2 is a functional block diagram showing an example of the centralized control device 10 and the local control device 30 according to the present embodiment.

The communication system 7 includes a wireless communication device 71 connected to the centralized control device 10, a wireless communication device 72 connected to the local control device 30, and a wireless communication device 73 connected to the pressure sensor 6. In FIG. 2, only one wireless communication device 73 is described for convenience, but each of the plurality of pressure sensors 6 is provided.

The centralized control device 10 can wirelessly communicate with each of the plurality of local control devices 30 via the communication system 7. The centralized control device 10 transmits a command signal to the local control device 30 via the communication system 7.

The centralized control device 10 can wirelessly communicate with each of the plurality of pressure sensors 6 via the communication system 7. The pressure sensor 6 transmits the detected pressure value Ps to the centralized control device 10 via the communication system 7.

The centralized control device 10 includes a computer system, and has an arithmetic processing unit and a storage device. The arithmetic processing unit includes a microprocessor such as a CPU (Central Processing Unit). The storage device includes a non-volatile memory such as ROM (Read Only Memory) or a volatile memory such as RAM (Random Access Memory). Similarly, the local control device 30 includes a computer system and includes an arithmetic processing unit and a storage device.

The centralized traffic control device 10 includes a detection pressure acquisition unit 11, a representative pressure determination unit 12, an operating number control unit 13, a storage unit 14, and an input / output unit 15.

The detected pressure acquisition unit 11 acquires the detected pressure value Ps from each of the plurality of pressure sensors 6 via the communication system 7. The position data indicating the detection position of the pressure sensor 6 is stored in the storage unit 14. The pressure sensor 6 transmits the detected pressure value Ps together with the identification data of the pressure sensor 6 to the centralized control device 10. The detected pressure acquisition unit 11 can acquire the detected pressure value Ps whose detection position is specified based on the position data of the pressure sensor 6 and the identification data of the pressure sensor 6 stored in the storage unit 14.

The representative pressure determination unit 12 determines the representative pressure value Pm of the compressed air based on the detection pressure values Ps of the plurality of pressure sensors 6 acquired by the detection pressure acquisition unit 11. In the present embodiment, the representative pressure value Pm is an average value of the detected pressure values Ps at a plurality of detection positions set in the network pipeline 4 and the use point 3. The representative pressure determining unit 12 sets the representative pressure value Pm as the average of the detected pressure values Ps of the plurality of network pipeline pressure sensors 63 acquired by the detected pressure acquisition unit 11 and the detected pressure values Ps of the plurality of use point pressure sensors 65. Calculate the value.

When calculating the average value of the detected pressure values Ps at a plurality of detection positions, it is preferable to process the pressure data to be averaged so as not to include abnormal data due to sudden fluctuations in air pressure or the like. Specifically, an upper limit threshold value and a lower limit threshold value for removing abnormal data are set, and when the pressure data at a specific detection position is not within the range of the upper limit threshold value and the lower limit threshold value, the pressure data is not adopted. do. By processing in this way, an appropriate representative pressure value Pm can be determined. It is preferable to perform the same processing when calculating the weighted average value of the detected pressure values Ps at a plurality of detection positions described later.

The operating number control unit 13 outputs a command signal for collectively remote control of the operation of the plurality of air compressor groups 5 to the local control device 30 based on the representative pressure value Pm determined by the representative pressure determination unit 12. do.

The centralized control device 10 is connected to the input device 16. The input device 16 includes, for example, at least one of a computer keyboard, a switch button, and a touch panel. The input device 16 is operated by the user of the compressed air supply system 1. Upon being operated by the user, the input device 16 generates input data and outputs it to the centralized control device 10.

The local control device 30 includes a detection pressure acquisition unit 31, a command signal acquisition unit 32, a local control unit 33, a storage unit 34, and an input / output unit 35.

The detected pressure acquisition unit 31 acquires the detected pressure value Ps from the pressure sensor 6. The command signal acquisition unit 32 acquires a command signal from the centralized control device 10.

The local control unit 33 controls the air compressor group 5. The control of the air compressor group 5 includes the start, stop, and capacity control of the air compressor 50. In the present embodiment, the local control unit 33 controls the air compressor group 5 in either the remote mode or the local mode. The remote mode is a control mode in which a plurality of air compressors 50 are heteronomously controlled by command signals from the centralized control device 10. The local mode is a control mode in which a plurality of air compressors 50 are autonomously controlled without depending on a command signal from the centralized control device 10.

[motion]
Next, the operation of the compressed air supply system 1 according to the present embodiment will be described. FIG. 3 is a flowchart showing an example of the operation of the compressed air supply system 1 according to the present embodiment. The processing of the centralized traffic control device 10 is carried out at a predetermined control cycle.

The plurality of pressure sensors 6 detect the pressure of the compressed air at each of the plurality of detection positions set in the flow path of the compressed air in the compressed air supply system 1. The detected pressure value Ps detected by the pressure sensor 6 is transmitted to the centralized control device 10 via the communication system 7.

The detection pressure acquisition unit 11 of the centralized control device 10 acquires the detection pressure values Ps at a plurality of detection positions set in the network line 4 including the receiver tank 20 and the use point 3 (step SA1). The representative pressure determination unit 12 calculates the average value of the detected pressure values Ps at the plurality of detection positions set in the network pipeline 4 and the use point 3 (step SA2).

The representative pressure determination unit 12 determines the representative pressure value Pm (step SA3). In the present embodiment, the representative pressure determination unit 12 determines the average value of the detected pressure values Ps calculated in step SA2 as the representative pressure value Pm.

The operating number control unit 13 outputs a command signal for collectively remote controlling the operation of the plurality of air compressor groups 5 based on the representative pressure value Pm determined in step SA3 (step SA4). The command signal is transmitted to each of the plurality of local control devices 30 via the communication system 7.

The command signal acquisition unit 32 of the local control device 30 acquires the command signal transmitted from the centralized control device 10 via the communication system 7. The local control unit 33 controls the air compressor group 5 based on the command signal. In the present embodiment, the number of the plurality of air compressor groups 5 is controlled based on the representative pressure value Pm. Based on the representative pressure value Pm, the number of operating units of the air compressor group 5 is increased or decreased, and the flow rate of the compressed air sent from the air compressor group 5 is adjusted. When the process of step SA4 is completed, the process returns to the process of step SA1. That is, the operating number control unit 13 continues the remote control based on the representative pressure value Pm updated in real time.

[effect]
As described above, according to the present embodiment, the representative pressure value Pm of the compressed air is determined from the detected pressure values Ps of the plurality of pressure sensors 6, and the plurality of air compressors are determined based on the determined representative pressure value Pm. The operation of group 5 is collectively remotely controlled.

According to the present embodiment, the number of the plurality of air compressor groups 5 is controlled based on the representative pressure value Pm, so that the compressed air generated at the plurality of feed points 2 is appropriate for each of the plurality of use points 3. It is supplied with a high pressure. Therefore, it is suppressed that the pressure of the compressed air is insufficient at the use point 3.

Further, according to the present embodiment, the operation of the plurality of air compressor groups 5 is remotely controlled by the centralized control device 10. As a result, the communication cable connecting the centralized control device 10 and the local control device 30 is omitted. Further, since the work of laying the communication cable becomes unnecessary, for example, it is possible to easily cope with the expansion of the feed point 2.

Further, in the present embodiment, the representative pressure value Pm is an average value of the detected pressure values Ps at a plurality of detection positions set in the network pipeline 4 and the use point 3. As a result, it is possible to prevent the pressure of the compressed air supplied to each of the plurality of use points 3 from becoming insufficient.

In the flow path of compressed air, the pressure at a specific detection position may fluctuate due to, for example, the pressure loss in the pipeline, the operating state of the air compressor group 5, and the air consumption state of use point 3. .. For example, when only one detection position is set in the network pipeline 4, if the air compressor group 5 is controlled based on the detection pressure value Ps at that one detection position, the detection pressure value fluctuates locally. The air compressor group 5 will be controlled based on Ps. As a result, it may be difficult to operate the air compressor group 5 with an appropriate number of operating units, or it may be difficult to supply compressed air to the use point 3 at an appropriate pressure. Further, for example, if the operation of the air compressor group 5 is controlled based on the detected pressure value Ps at the detection position set at one location, the supply amount of compressed air may be excessive or insufficient at other locations.

According to this embodiment, the average value of the detected pressure values Ps at a plurality of detection positions is used as the representative pressure value Pm. Therefore, the fluctuation of the pressure at each detection position is canceled out, and the influence of the fluctuation of the pressure on the number control is suppressed. Therefore, compressed air is supplied to each of the plurality of use points 3 at an appropriate pressure.

Further, in the present embodiment, the booster compressor 55 for boosting the compressed air supplied to the specific use point 3 among the plurality of use points 3 is provided. Therefore, the supply pressure of the compressed air at the feed point 2 can be lowered, and the pressure loss generated in the pipeline is reduced. As a result, the power consumption of the air compressor group 5 is suppressed, and the energy saving effect of the compressed air supply system 1 can be enhanced.

In the present embodiment, the representative pressure value Pm may be a weighted average value weighted with the detected pressure value Ps at the specific detection position among the plurality of detection positions. For example, the representative pressure determining unit 12 weights the detected pressure values Ps at the specific detection positions set at the specific use points 3s among the detected pressure values Ps at the plurality of detection positions set at the plurality of use points 3. The average value may be determined as the representative pressure value Pm. As the specific use point 3s, for example, an important use point in which the entire production facility related to the specific use point 3s is stopped when the pressure or flow rate of the supplied compressed air is insufficient is exemplified.

In the present embodiment, the specific use point 3s is the use point 3 having the largest amount of compressed air used per unit time among the plurality of use points 3. As the unit time, for example, at least one of one hour, one day, and one operating time in one day is exemplified. The specific use point 3s may be specified by the user of the compressed air supply system 1. The user can operate the input device 16 to specify the specific use point 3s from the plurality of use points 3 provided in the industrial facility.

The representative pressure determination unit 12 determines a weighted average value weighted with the detected pressure value Ps at the specific detection position set at the specific use point 3s as the representative pressure value Pm. When calculating the average value of the detected pressure values Ps, the detected pressure value Ps at the specific detection position set at the specific use point 3s is weighted, so that the influence of the pressure fluctuation on the number control is suppressed and the specific use. Compressed air is supplied to point 3s at an appropriate pressure.

In the present embodiment, the representative pressure value Pm is the average value of the detected pressure values Ps at the plurality of detection positions set in the main pipeline 40 and the use point 3. The representative pressure value Pm may be the average value of the detected pressure values Ps at a plurality of detection positions set in the main pipeline 40 and the youth pipeline 9, or may be set in the main pipeline 40, the youth pipeline 9, and the use point 3. It may be the average value of the detected pressure values Ps at a plurality of detection positions.

In the present embodiment, the detected pressure value Ps is preferably calculated as a smoothed moving average value of time series data sampled at a predetermined cycle. When the pressure sampling data changes drastically with time according to the fluctuation of the amount of compressed air used, the local pressure can be accurately represented by using the detected pressure value Ps as the moving average value. The pressure sensor 6 in which it is desirable to use the detected pressure value Ps as a moving average value is, for example, a youth pipeline pressure sensor 64 or a use point pressure sensor 65.

Second embodiment.
The second embodiment will be described. In the following description, the same or equivalent components as those in the above-described embodiment are designated by the same reference numerals, and the description thereof will be simplified or omitted.

In the present embodiment, an example in which the representative pressure value Pm is the detected pressure value Ps at the specific use point 3s among the plurality of use points 3 will be described. The specific use point 3s is the use point 3 having the largest amount of compressed air used per unit time among the plurality of use points 3.

In this embodiment, the specific use point 3s is changed depending on the time zone. The use point 3 in which the amount of compressed air used per unit time is the largest may change depending on the time zone. For example, in the first time zone such as daytime, the first use point 3 among the plurality of use points 3 becomes the specific use point 3s, and in the second time zone such as nighttime, the second use point 3 becomes. It may be a specific use point 3s.

FIG. 4 is a flowchart showing an example of the operation of the compressed air supply system 1 according to the present embodiment. The detection pressure acquisition unit 11 of the centralized traffic control device 10 acquires the detection pressure value Ps at the specific use point 3s corresponding to at least the first time zone (step SB1). The representative pressure determination unit 12 determines the detected pressure value Ps acquired in step SB1 as the representative pressure value Pm (step SB2). The operating number control unit 13 outputs a command signal for collectively remote controlling the operation of the plurality of air compressor groups 5 based on the representative pressure value Pm determined in step SB2 (step SB3).

The command signal acquisition unit 32 of the local control device 30 acquires the command signal transmitted from the centralized control device 10 via the communication system 7. The local control unit 33 controls the air compressor group 5 based on the command signal.

The representative pressure determination unit 12 determines whether or not to change the specific use point 3s (step SB4). In the present embodiment, the representative pressure determination unit 12 determines that the specific use point 3s is changed when the transition from the first time zone to the second time zone is performed. When it is determined in step SB4 that the specific use point 3s is to be changed (step SB4: Yes), the representative pressure determination unit 12 sets the specific use point 3s corresponding to the first time zone to the specific use point corresponding to the second time zone. Change to 3s (step SB5). After the specific use point 3s is changed, the centralized traffic control device 10 returns to the process of step SB1. On the other hand, when it is determined in step SB4 that the specific use point 3s is not changed (step SB4: No), the centralized traffic control device 10 returns to the process of step SB1. That is, the operating number control unit 13 continues the remote control based on the representative pressure value Pm updated in real time.

When the specific use point 3s is changed in step SB5, the representative pressure determination unit 12 acquires the detected pressure value Ps at the changed specific use point 3s and determines it as the representative pressure value Pm (steps SB1 and SB2). The operating number control unit 13 collectively remotely controls the operation of the plurality of air compressor groups 5 based on the representative pressure value Pm which is the detected pressure value Ps at the changed specific use point 3s (step SB3).

As described above, according to the present embodiment, the detected pressure value Ps at the specific use point 3s is determined as the representative pressure value Pm. As a result, the operating number control unit 13 can control the number of the plurality of air compressor groups 5 so that the compressed air is supplied to the specific use point 3s at an appropriate pressure. By focusing on detecting the pressure of a high-load specific use point 3s that uses a large amount of compressed air and setting the detected pressure value Ps at the specific use point 3s as the representative pressure value Pm, the pressure is supplied to the specific use point 3s. Insufficient supply of compressed air is suppressed.

In the present embodiment, the specific use point 3s may be the use point 3 designated by the user of the compressed air supply system 1.

In the present embodiment, the specific use point 3s is changed depending on the time zone, and the detection position is sequentially changed according to the time zone. The specific use point 3s does not have to be changed depending on the time zone. In that case, the detection position is fixed to one specific use point 3s.

Third embodiment.
The third embodiment will be described. In the following description, the same or equivalent components as those in the above-described embodiment are designated by the same reference numerals, and the description thereof will be simplified or omitted.

In the present embodiment, an example in which the representative pressure value Pm is the minimum value of the detected pressure value Ps at each of the plurality of use points 3 will be described. That is, in the present embodiment, the detected pressure value Ps at the use point 3 where the pressure of the compressed air is the most insufficient among the plurality of use points 3 is determined as the representative pressure value Pm.

FIG. 5 is a flowchart showing an example of the operation of the compressed air supply system 1 according to the present embodiment. The detection pressure acquisition unit 11 of the centralized traffic control device 10 acquires the detection pressure values Ps at each of the plurality of use points 3 (step SC1). The representative pressure determination unit 12 compares the detected pressure values Ps at each of the plurality of use points 3. When the four use points 3 exist, the representative pressure determination unit 12 determines whether or not the detected pressure value Ps at the first use point 3 among the four use points 3 is the minimum value (step SC2).

When it is determined in step SC2 that the detected pressure value Ps at the first use point 3 is the minimum value (step SC2: Yes), the representative pressure determining unit 12 determines the detected pressure value Ps at the first use point 3. It is determined as a representative pressure value Pm (step SC5). When it is determined in step SC2 that the detected pressure value Ps at the first use point 3 is not the minimum value (step SC2: No), the representative pressure determination unit 12 determines the second use point 3 out of the four use points 3. It is determined whether or not the detected pressure value Ps in is the minimum value (step SC3).

When it is determined in step SC3 that the detected pressure value Ps at the second use point 3 is the minimum value (step SC3: Yes), the representative pressure determining unit 12 determines the detected pressure value Ps at the second use point 3. It is determined as a representative pressure value Pm (step SC5). When it is determined in step SC3 that the detected pressure value Ps at the second use point 3 is not the minimum value (step SC3: No), the representative pressure determination unit 12 determines the third use point 3 out of the four use points 3. It is determined whether or not the detected pressure value Ps in is the minimum value (step SC4).

When it is determined in step SC4 that the detected pressure value Ps at the third use point 3 is the minimum value (step SC4: Yes), the representative pressure determining unit 12 determines the detected pressure value Ps at the third use point 3. It is determined as a representative pressure value Pm (step SC5). When it is determined in step SC4 that the detected pressure value Ps at the third use point 3 is not the minimum value (step SC4: No), the representative pressure determining unit 12 represents the detected pressure value Ps at the fourth use point 3. It is determined as the pressure value Pm (step SC5).

The operating number control unit 13 outputs a command signal for collectively remote controlling the operation of the plurality of air compressor groups 5 based on the representative pressure value Pm determined in step SC5 (step SC6). The local control unit 33 controls the air compressor group 5 based on the command signal. When the process of step SC6 is completed, the process returns to the process of step SC1. That is, the operating number control unit 13 continues the remote control based on the representative pressure value Pm updated in real time.

As described above, according to the present embodiment, the minimum value of the detected pressure value Ps at each of the plurality of use points 3 is determined as the representative pressure value Pm. As a result, the operating number control unit 13 can control the number of the plurality of air compressor groups 5 so that the compressed air is supplied at an appropriate pressure to the use point 3 where the pressure of the compressed air is the shortest. ..

Of the plurality of use points 3, the use point 3 indicating the minimum value of the detected pressure value Ps changes with time, or changes based on the operating state of the feed point 2 or the air consumption state of the use point 3. By monitoring the detected pressure value Ps at each of the plurality of use points 3, even if the use point 3 indicating the minimum value of the detected pressure value Ps changes, the centralized traffic control device 10 performs the minimum of the detected pressure value Ps. A plurality of air compressor groups 5 can be controlled by using the value as the representative pressure value Pm. As a result, the compressed air is supplied at an appropriate pressure to the use point 3 where the pressure of the compressed air is the shortest.

Fourth embodiment.
A fourth embodiment will be described. In the following description, the same or equivalent components as those in the above-described embodiment are designated by the same reference numerals, and the description thereof will be simplified or omitted.

In the present embodiment, a plurality of supply and demand areas 100 including at least one feed point 2 and at least one use point 3 are defined, and a representative pressure value Pm is provided in the specific supply and demand area 100s among the plurality of supply and supply areas 100. An example in which the detected pressure value Ps of the existing pressure sensor 6 is described will be described. As the specific supply and demand area 100s, for example, an important supply and demand area in which the entire production facility related to the use point 3 included in the specific supply and demand area 100s is stopped when the pressure or flow rate of compressed air is insufficient is exemplified.

FIG. 6 is a diagram for explaining an example of the supply / demand area 100 according to the present embodiment. As shown in FIG. 6, in an industrial facility, a plurality of supply and demand areas 100 including at least one feed point 2 and at least one use point 3 are defined. In this embodiment, four supply and demand areas 100A, 100B, 100C, and 100D are defined.

One supply / supply area 100 is defined by the use point 3 having the shortest distance between the feed point 2 of any of the plurality of feed points 2 and the feed point 2. In other words, one feed point 2 is connected to one of the plurality of connection portions 8C, and the use point 3 is connected to the connection portion 9C having the shortest distance between the connection portions 8C. The supply and demand area 100 is defined.

One supply / supply area 100 is defined by one of the plurality of feed points 2 and the use point 3 in which the compressed air sent from the feed point 2 is supplied with the smallest pressure loss. May be good. In other words, one supply / supply area 100 may be defined by the feed point 2 and the use point 3 connected by the distribution channel having the smallest pressure loss in the network pipeline 4.

In the present embodiment, the specific supply / demand area 100s is changed depending on the time zone. For example, in the first time zone, the supply and demand area 100A becomes the specific supply and demand area 100s, in the second time zone, the supply and demand area 100B becomes the specific supply and demand area 100s, and in the third time zone, the supply and demand area 100C becomes the specific supply and demand area. It becomes 100s, and in the fourth time zone, the supply and demand area 100D becomes the specific supply and demand area 100s. When the representative pressure determination unit 12 reaches a specific time zone, the representative pressure value Ps determines the detected pressure value Ps of the pressure sensor 6 provided in the specific supply / demand area 100s corresponding to the time zone as the representative pressure value Pm.

FIG. 7 is a flowchart showing an example of the operation of the compressed air supply system 1 according to the present embodiment. The detection pressure acquisition unit 11 of the centralized control device 10 acquires the detection pressure value Ps of the pressure sensor 6 provided in the specific supply / demand area 100s corresponding to the first time zone (step SD1). The representative pressure determination unit 12 determines the detected pressure value Ps acquired in step SD1 as the representative pressure value Pm (step SD2).

In the present embodiment, the representative pressure determination unit 12 determines the detected pressure value Ps of the network pipeline pressure sensor 63 provided in the specific supply / demand area 100s as the representative pressure value Pm. The representative pressure determination unit 12 includes a receiver tank pressure sensor 61, a feed line pressure sensor 62, a network line pressure sensor 63, a youth line pressure sensor 64, and a use point pressure sensor provided in the specific supply / supply area 100s. At least one detected pressure value Ps of 65 can be determined as a representative pressure value Pm.

The operating number control unit 13 outputs a command signal for collectively remote controlling the operation of the plurality of air compressor groups 5 based on the representative pressure value Pm determined in step SD2 (step SD3). The local control unit 33 controls the air compressor group 5 based on the command signal.

The representative pressure determination unit 12 determines whether or not to change the specific supply / demand area 100s (step SD4). In the present embodiment, the representative pressure determination unit 12 determines that the specific supply / demand area 100s is changed when the transition from the first time zone to the second time zone is performed. When it is determined in step SD4 that the specific supply / demand area 100s is to be changed (step SD4: Yes), the representative pressure determination unit 12 sets the specific supply / supply area 100s corresponding to the first time zone to the specific supply / supply area corresponding to the second time zone. Change to 100s (step SD5). After the specific supply / demand area 100s is changed, the centralized control device 10 returns to the process of step SD1. On the other hand, when it is determined in step SD4 that the specific supply / demand area 100s is not changed (step SD4: No), the centralized traffic control device 10 returns to the process of step SD1. That is, the operating number control unit 13 continues the remote control based on the representative pressure value Pm updated in real time.

When the specific supply / supply area 100s is changed in step SD5, the representative pressure determination unit 12 acquires the detected pressure value Ps of the pressure sensor 6 provided in the changed specific supply / supply area 100s and determines it as the representative pressure value Pm. (Steps SD1 and SD2). The operating number control unit 13 collectively remotes the operation of the plurality of air compressor groups 5 based on the representative pressure value Pm which is the detected pressure value Ps of the pressure sensor 6 provided in the specified supply / demand area 100s after the change. Control (step SD3).

As described above, according to the present embodiment, the detected pressure value Ps of the pressure sensor 6 provided in the specific supply / demand area 100s is determined as the representative pressure value Pm. As a result, the operating number control unit 13 can control the number of the plurality of air compressor groups 5 so that the compressed air having an appropriate pressure is preferentially supplied to the specific supply and demand area 100s.

In the present embodiment, the specific supply / demand area 100s is changed depending on the time zone, and the detection position is sequentially changed according to the time zone. The specific supply / demand area 100s does not have to be changed depending on the time zone. In that case, the detection position is fixed at one place.

In the present embodiment, the specific supply / demand area 100s may be designated by the user of the compressed air supply system 1. The user can operate the input device 16 to specify the specific supply and demand area 100s from the plurality of supply and demand areas 100 provided in the industrial facility.

Fifth embodiment.
A fifth embodiment will be described. In the following description, the same or equivalent components as those in the above-described embodiment are designated by the same reference numerals, and the description thereof will be simplified or omitted.

In this embodiment, an example of the operation of the local control device 30 will be described. FIG. 8 is a diagram showing an example of the supply / demand area 100 according to the present embodiment. As described above, in an industrial facility, a supply and demand area 100 including at least one feed point 2 and at least one use point 3 is defined. A plurality of pressure sensors 6 (61, 62, 63, 64, 65) for detecting the pressure of compressed air are provided in the supply / demand area 100.

In the present embodiment, the air compressor group 5 that generates compressed air at the feed point 2 in the supply and demand area 100 has a plurality of air compressors 50 having different discharge amounts. In the present embodiment, the air compressor 50 includes a first air compressor 51 capable of discharging compressed air with a first discharge amount and a second air compressor capable of discharging compressed air with a second discharge amount smaller than the first discharge amount. It includes 52 and a third air compressor 53 capable of discharging compressed air with a third discharge amount smaller than the second discharge amount.

The local control device 30 is a remote mode in which a plurality of air compressors 50 (51, 52, 53) provided in the supply / demand area 100 are heteronomously controlled by a command signal from the centralized control device 10, or a plurality of air compressors 50 ( It operates in a local mode in which 51, 52, 53) are autonomously controlled without depending on a command signal from the centralized control device 10. The local control device 30 controls the air compressor group 5 in the supply / demand area 100 in which the local control device 30 is provided by heteronomous control or autonomous control.

In the remote mode, the local control unit 33 heteronomously controls the air compressor group 5 based on the command signal transmitted from the centralized control device 10. In the local mode, the local control unit 33 autonomously controls the air compressor group 50 based on the detected pressure value Ps of the predetermined pressure sensor 6 (for example, the receiver tank pressure sensor 61).

For example, when a communication failure occurs between the centralized control device 10 and the local control device 30 and the air compressor group 5 cannot be heteronomously controlled by the command signal from the centralized control device 10, the local control device 30 is released from the remote mode. Move to local mode. Further, when the pressure of the compressed air in the supply / demand area 100 drops sharply, the local control device 30 shifts from the remote mode to the local mode. For example, all of the air compressors 50 in the supply and demand area 100A are stopped, and the compressed air from the feed points 2 in the supply and demand areas 100B, 100C, and 100D is supplied to the use point 3 in the supply and demand area 100A. When the pressure of the compressed air in the area 100A drops sharply and the control by the command signal from the centralized control device 10 is continued, the supply amount of the compressed air cannot be increased instantaneously, and the supply and demand area 100A There is a possibility of running out of compressed air at use point 3. When the pressure of the compressed air in the supply / supply area 100A drops sharply, the remote mode is shifted to the local mode, and the autonomous control by the local control device 30 provided in the supply / supply area 100A is performed to supply the compressed air. The amount can be increased instantly, and the situation where the compressed air is insufficient at the use point 3 of the supply / demand area 100A is avoided.

In the present embodiment, when the detected pressure value Ps of the pressure sensor 6 (for example, the receiver tank pressure sensor 61) in the supply / demand area 100 drops to the set value Ph, the local control device 30 shifts from the remote mode to the local mode. One of the startable air compressors 50 is started.

The local control device 30 measures the pressure drop rate by the pressure sensor 6 in the supply / demand area 100 in the remote mode. In the remote mode, when the detected pressure value Ps of the pressure sensor 6 drops to the set value Ph, the local control device 30 shifts from the remote mode to the local mode and obtains a required discharge amount according to the measured pressure drop speed. The startable air compressor 50 is started.

The set value Ph is specified by, for example, the user of the compressed air supply system 1 and is stored in the storage unit 34. The set value Ph is set to a value at which the operation of the production equipment related to the feed point 2 and the use point 3 included in the supply and demand area 100 can be maintained.

The startable air compressor 50 specifically refers to an air compressor that is stopped and has passed the inching prevention time. In the local control device 30, inching prevention time is set for each air compressor 50 (51, 52, 53) in order to prevent seizure due to the oscillating operation of the motor, and the inching prevention time is set from the time when the motor is stopped. The restart of the motor is prohibited until the above is passed.

FIG. 9 is a diagram for explaining an example of the pressure drop rate at the detection position of the supply / demand area 100 according to the present embodiment. In the graph shown in FIG. 9, the horizontal axis represents time and the vertical axis represents the detected pressure value Ps of the pressure sensor 6. At the time point ta, the local control device 30 is operating in the remote mode, and the centralized control device 10 selects and activates the required number of air compressors 50 according to the representative pressure value Pm from the supply and demand areas 100A to D. ing. The pressure sensor 6 monitors the pressure of compressed air at the detection position of the supply and demand area 100. The detection pressure acquisition unit 31 of the local control device 30 acquires the detection pressure value Ps from the pressure sensor 6 at a predetermined sampling cycle. The detection pressure acquisition unit 31 measures the pressure decrease rate indicating the amount of decrease in the pressure of the compressed air per unit time at the detection position of the supply / demand area 100 based on the detection pressure value Ps from the pressure sensor 6.

When the detected pressure value Ps of the pressure sensor 6 is equal to or higher than the set value Ph, the local control device 30 operates in the remote mode. On the other hand, when the detected pressure value Ps of the pressure sensor 6 drops to the set value Ph, the local control device 30 shifts from the remote mode to the local mode.

FIG. 9 schematically shows the change in the detected pressure value Ps when the pressure drop rate is the first speed V1, the second speed V2 lower than the first speed V1, and the third speed V3 lower than the second speed V2. Shown in.

When the pressure decreasing speed is the first speed V1, the detected pressure value Ps of the pressure sensor 6 drops to the set value Ph at the first time point t1. When the pressure drop rate is the first speed V1, the local control device 30 shifts from the remote mode to the local mode at the first time point t1.

When the pressure drop speed is the second speed V2, the detected pressure value Ps of the pressure sensor 6 drops to the set value Ph at the second time point t2. The time between the time point ta and the second time point t2 is longer than the time between the time point ta and the first time point t1. When the pressure drop rate is the second speed V2, the local control device 30 shifts from the remote mode to the local mode at the second time point t2.

When the pressure drop speed is the third speed V3, the detected pressure value Ps of the pressure sensor 6 drops to the set value Ph at the third time point t3. The time between the time point ta and the third time point t3 is longer than the time between the time point ta and the second time point t2. When the pressure drop rate is the third speed V3, the local control device 30 shifts from the remote mode to the local mode at the third time point t3.

When the detected pressure value Ps of the pressure sensor 6 drops to the set value Ph, the local control device 30 activates the startable air compressor 50 that can obtain the required discharge amount based on the measured pressure drop rate.

In the present embodiment, the local control device 30 activates the first air compressor 51 when the measured pressure drop speed is within the first speed range including the first speed V1. The local control device 30 has a second air compressor 52 having a smaller discharge rate than the first air compressor 51 when the measured pressure drop speed is within the second speed range including the second speed V2 which is lower than the first speed V1. To start. The local control device 30 has a third air compressor 53 having a smaller discharge rate than the second air compressor 52 when the measured pressure drop speed is within the third speed range including the third speed V3 which is lower than the second speed V2. To start.

The first speed range including the first speed V1, the second speed range including the second speed V2, and the third speed range including the third speed V3 are set so as not to overlap each other. Specifically, when the pressure drop rate is VL, the first speed range is Va ≧ VL> Vb, the second speed range is Vb ≧ VL> Vc, and the third speed range is Vc ≧ VL> Vd. .. Here, Va, Vb, Vc, and Vd correspond to the upper limit value or the lower limit value of each range.

FIG. 10 is a flowchart showing an example of the operation of the compressed air supply system 1 according to the present embodiment. At the start, the local controller 30 is operating in remote mode. When operating in the remote mode, for example, in a state where all of the plurality of air compressors 50 in the supply / supply area 100A are stopped or some of them are started, the supply / supply area 100A has another supply / supply area 100B, Compressed air is supplied from 100C and 100D. The pressure sensor 6 provided in the supply / demand area 100A detects the pressure of the compressed air. The detection pressure acquisition unit 31 of the local control device 30 acquires the detection pressure value Ps from the pressure sensor 6 (step SE1).

The detection pressure acquisition unit 31 determines whether or not the detected pressure value Ps has dropped to the set value Ph (step SE2). When it is determined in step SE2 that the detected pressure value Ps is larger than the set value Ph (step SE2: No), the local control device 30 returns to the process of step SE1. When it is determined in step SE2 that the detected pressure value Ps has dropped to the set value Ph (step SE2: Yes), the local control device 30 shifts from the remote mode to the local mode (step SE3).

When the mode shifts to the local mode, the local control unit 33 determines whether or not there is a stopped air compressor in the supply and demand area 100A (step SE4). When it is determined in step SE4 that there is a stopped air compressor 50 (step SE4: Yes), the local control device 30 proceeds to the process of step SE5. When it is determined in step SE4 that there is no stopped air compressor 50 (step SE4: No), the local control device 30 proceeds to the process of step SE11.

When it is determined that there is a stopped air compressor 50 in the supply / demand area 100A, the local control unit 33 determines whether or not the stopped air compressor 50 can be started (step SE5). For example, when there is no air compressor 50 for which the inching prevention time has not elapsed, it is determined that the air compressor 50 can be started (step SE5: Yes), and the local control device 30 proceeds to the process of step SE6. When there is an air compressor 50 for which the inching prevention time has not elapsed, it is determined that the air compressor 50 cannot be started (step SE5: No), and the local control device 30 waits until the inching prevention time elapses.

When it is determined that the stopped air compressor 50 can be started, the detection pressure acquisition unit 31 differentiates the pressure detection value Ps of the pressure sensor 6 to obtain the pressure reduction speed, and this pressure reduction speed is in the first speed range. It is determined whether or not the pressure is inside (step SE6). When it is determined in step SE6 that the pressure drop speed is within the first speed range (step SE6: Yes), the local control unit 33 activates the first air compressor 51 (step SE7). When it is determined in step SE6 that the pressure decrease rate is not within the first speed range (step SE6: No), the detection pressure acquisition unit 31 determines whether or not the pressure decrease rate is within the second speed range (step). SE8).

When it is determined in step SE8 that the pressure drop speed is within the second speed range (step SE8: Yes), the local control unit 33 activates the second air compressor 52 (step SE9). When it is determined in step SE8 that the pressure decrease rate is not within the second speed range (step SE8: No), the detection pressure acquisition unit 31 determines that the pressure decrease rate is within the third speed range. The local control unit 33 activates the third air compressor 53 (step SE10).

Local control when any of the air compressors 51, 52, 53 is started by the processing of steps SE7 , SE9, SE10, or when all the air compressors 51, 52, 53 are started by the judgment of step SE4. The device 30 shifts from the local mode to the remote mode (step SE11).

As described above, in the present embodiment, when the detected pressure value Ps of the pressure sensor 6 drops to the set value Ph, the local control device 30 shifts from the remote mode to the local mode and any of them can be activated. Air compressor 50 is activated. As a result, the situation where the supply amount of compressed air is insufficient in the supply and demand area 100 is avoided.

Further, in the present embodiment, the pressure decrease rate of the compressed air in the supply / demand area 100 is measured by using the pressure sensor 6, and when the detected pressure value Ps of the pressure sensor 6 drops to the set value Ph, the local control device 30 determines. The mode shifts from the remote mode to the local mode, and the startable air compressor 50 that can obtain the required discharge amount according to the measured pressure drop rate is started. By activating the air compressor 50 selected based on the measured pressure drop rate, compressed air corresponding to the peak amount of air consumption in the supply / demand area 100 is generated.

For example, if the air compressor 50 having a small discharge amount is started when the pressure drop rate is large, it may be difficult to cover the insufficient compressed air in the supply and demand area 100A. On the other hand, if the air compressor 50 having a large discharge amount is started when the pressure decrease rate is small, an overshoot in which the pressure of the compressed air suddenly rises may occur, and an appropriate pressure may not be obtained. In the present embodiment, the larger the pressure decrease rate, the larger the discharge amount of the air compressor 50 is activated, and the smaller the pressure decrease rate, the smaller the discharge amount of the air compressor 50 is activated. Therefore, the occurrence of overshoot is suppressed. At the same time, the compressed air that is insufficient in the supply / demand area 100 can be instantly generated.

In the present embodiment, three air compressors 50 having different discharge amounts are provided, and one of the three air compressors 50 is activated based on the pressure drop rate. did. In addition to this, when the pressure drop rate exceeds the third speed range, two air compressors 50 may be started or three air compressors 50 may be activated depending on the magnitude of the pressure drop rate. It may be started. Further, the number of air compressors 50 arranged in one supply / supply area 100 may be two or any number of four or more.

Further, in the present embodiment, when the detected pressure value Ps of the predetermined pressure sensor 6 drops to the set value Ph, the remote mode is shifted to the local mode and the startable air compressor 50 is started. Instead of this, the detected pressure values Ps of a plurality of pressure sensors 6 are monitored at the same time, and when the detected pressure value Ps of any of the pressure sensors 6 drops to the set value Ph, the remote mode is shifted to the local mode and the operation is started. A possible air compressor 50 may be activated. In this case, when the detected pressure value Ps of any of the pressure sensors 6 has not dropped to the set value Ph, the local control device 30 operates in the remote mode.

Other embodiments.
In each of the above-described embodiments, a plurality of air compressors 50 are provided at one feed point 2. For example, in the first to fourth embodiments described above, one air compressor 50 may be provided at one feed point 2. That is, the concept may be such that the air compressor group 5 is composed of one air compressor 50.

In each of the above-described embodiments, the receiver tank 20 is provided in the feed line 8 of the network line 4. Since the receiver tank 20 is a buffer tank for compressed air, it may be provided in the main pipeline 40 of the network pipeline 4. The receiver tank 20 may be provided, for example, at the connection portion 8C between the feed line 8 and the main line 40. Further, the receiver tank 20 may be used as a buffer tank for compressed air for each feed point 2, and may be provided in the youth pipeline 9 or the connection portion 9C.

In each of the above-described embodiments, the network pipeline 4 is a loop-type pipeline. As shown in FIG. 11, the network pipeline 4 may be a mesh type pipeline. The mesh type pipeline means a pipeline in which the pipelines are connected in a mesh pattern and have a plurality of intersections. As shown in FIG. 12, the network pipeline 4 may be a tree-shaped pipeline. A tree-shaped pipeline is a pipeline having at least one branch and at least two ends. As shown in FIG. 13, the network pipeline 4 may be a star-shaped pipeline. A star-shaped pipeline means a plurality of pipelines laid radially from a central point. In FIGS. 11, 12, and 13, a receiver tank 20 is arranged at an intersection or an end of the network pipeline 4, and a feed point 2 including an air compressor group 5 is connected to the receiver tank 20. The network pipeline 4 may be configured by a pipeline in which at least two of a loop type, a mesh type, a tree type, and a star type are combined.

In addition, each of the above-described embodiments can be combined as appropriate. For example, in the first time zone, the average value of the detected pressure values Ps at a plurality of detection positions is determined as the representative pressure value Pm, and in the second time zone, the detected pressure value Ps at the specific use point 3s is used as the representative pressure value Pm. In the third time zone, the minimum value of the detected pressure value Ps at each of the plurality of use points 3 is determined as the representative pressure value Pm, and in the fourth time zone, the pressure sensor provided in the specific supply / supply area 100s. The detected pressure value Ps of 6 may be determined as the representative pressure value Pm. In this way, the method for determining the representative pressure value Pm may be changed over time.

1 ... Compressed air supply system, 2 ... Feed point, 3 ... Use point, 4 ... Network pipeline, 5 ... Air compressor group, 6 ... Pressure sensor, 7 ... Communication system, 8 ... Feed pipeline, 8C ... Connection part, 9 ... Youth pipeline, 9C ... Connection unit, 10 ... Centralized control device, 11 ... Detected pressure acquisition unit, 12 ... Representative pressure determination unit, 13 ... Operating number control unit, 14 ... Storage unit, 15 ... Input / output unit, 16 ... Input device, 20 ... Receiver tank, 21 ... On-off valve, 30 ... Local control device, 31 ... Detected pressure acquisition unit, 32 ... Command signal acquisition unit, 33 ... Local control unit, 34 ... Storage unit, 35 ... Input / output unit , 40 ... Main pipeline, 50 ... Air compressor, 51 ... 1st air compressor, 52 ... 2nd air compressor, 53 ... 3rd air compressor, 55 ... Booster compressor, 61 ... Receiver tank pressure sensor, 62 ... Feed pipeline pressure Sensor, 63 ... network pipeline pressure sensor, 64 ... youth pipeline pressure sensor, 65 ... youth point pressure sensor, 71 ... wireless communication device, 72 ... wireless communication device, 73 ... wireless communication device, 100 ... supply and demand area.

Claims (5)

A network pipeline connecting each of a plurality of feed points of compressed air and a plurality of use points of the compressed air,
A plurality of air compressor groups that generate the compressed air at each of the plurality of feed points,
A plurality of pressure sensors that detect the pressure of the compressed air at each of the plurality of detection positions set in the flow path of the compressed air, and
A centralized control device for collectively and remotely controlling the operation of the plurality of air compressor groups based on the representative pressure value of the compressed air determined from the detection pressure values of the plurality of pressure sensors .
The representative pressure value is an average value of the detected pressure values at the plurality of detection positions set in the network pipeline and the use point.
The average value is a weighted average value weighted with the detected pressure value at the specific detection position set for the specific use point among the use points.
Compressed air supply system. The specific use point includes the use point in which the amount of the compressed air used per unit time is the highest among the plurality of the use points.
The compressed air supply system according to claim 1. The representative pressure value includes the minimum value of the detected pressure value at each of the plurality of use points.
The compressed air supply system according to claim 1 or 2. A plurality of supply and demand areas including at least one feed point and at least one use point are defined.
The representative pressure value includes the detection pressure value of the pressure sensor provided in the specific supply / supply area among the plurality of the supply / supply areas.
The compressed air supply system according to any one of claims 1 to 3. The detected pressure value is calculated as a smoothed moving average value of time series data sampled at a predetermined cycle.
The compressed air supply system according to any one of claims 1 to 4.

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