JP2014010685A - Control system of mechanical equipment - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a control system of mechanical equipment by which a state of mechanical equipment can be properly grasped.SOLUTION: A control system of mechanical equipment includes: operation information storage means 104 for acquiring operation information of one or a plurality of compressors via a network N1 in real time, and storing the operation information in association with identification information of the compressors; and information processing means 109 for analyzing tendency of operation of the compressors within a predetermined period on the basis of the operation information read out from the operation information storage means 104, and storing an analysis result in association with the identification information of the compressors in management information storage means 107 as management information.

Description

  The present invention relates to a management system for managing information on machine equipment.

Compressors are used in a wide range of fields, including chemical plants, electronic equipment manufacturing, and food processing, and are indispensable for industry. In particular, in fields that dislike mixing oil, such as electronic equipment and food processing, there is an increasing demand for oil-free screw compressors that do not use oil.
In addition, since the performance of the compressor significantly affects the productivity of the product, there is a demand for appropriately understanding the state of the compressor.

For example, Patent Document 1 describes an abnormality prediction / lifetime management system that connects a customer's facility and a remote monitoring system with a communication line and notifies the monitoring system of diagnostic information and judgment information of the facility. Yes.
In the technique described in Patent Document 1, the operation status of equipment installed in a remote place is checked over each part, and from the standpoint of an expert, the discovery of abnormality and the contents of countermeasures are notified to the production factory, and maintenance is performed.

Japanese Patent Laid-Open No. 2003-50617

In the technique described in Patent Document 1, the contents of abnormality detection and countermeasures are notified to the production factory from the standpoint of an expert. However, as the number of customers (that is, the number of mechanical equipment to be maintained) increases, the expert It will be difficult to handle all of them alone.
That is, there is a demand for a system for appropriately grasping the state of each mechanical facility while processing a large amount of information obtained from the mechanical facility via a network.

  Then, this invention makes it a subject to provide the management system of a mechanical installation which can grasp | ascertain the state of a mechanical installation appropriately.

  In order to solve the above-mentioned problems, the present invention provides a storage of operation information in which operation information of one or more mechanical facilities is acquired through a network and stored in association with identification information of the mechanical facilities. And an operation information storage means for analyzing an operation tendency of the machine equipment in a predetermined period based on the operation information read from the operation information storage means and associating the analysis result with the identification information of the machine equipment. And an information processing means for storing the information.

  According to the present invention, it is possible to provide a mechanical equipment management system capable of appropriately grasping the state of mechanical equipment.

It is a block diagram which shows the outline | summary of the management system which concerns on one Embodiment of this invention. It is a block diagram which shows the structure of a compressor. It is a graph which shows the change of the discharge pressure of a compressor. It is a block diagram which shows the structure of an integrated management center. It is a sequence which shows the operation | movement regarding acquisition / publication processing of operation information. (A) is a display example of a login screen of a user personal computer, and (b) is a display example of a selection screen displayed after logging in. (A) is a display example of an operation information screen, and (b) is a display example of a setting information screen. It is a sequence which shows the operation | movement in connection with the acquisition process of failure and maintenance information. It is a sequence which shows the operation | movement in connection with the disclosure process of failure / maintenance information. (A) is a display example of a failure / maintenance information screen, and (b) is a display example of a failure information screen when a sensor abnormality occurs. It is a sequence which shows the operation | movement in connection with acquisition / publication processing of operation information. It is the example of a display of an operation information screen, (a) is a screen display example which shows transition of unloading time, (b) is a screen display example which shows transition of the number of unloading, (c) is discharge pressure. It is an example of a screen display which shows a change. It is a sequence which shows the operation | movement in connection with acquisition / disclosure processing of device information. (A) is a graph which shows the change of the discharge pressure of several compressors, (b) is a graph which shows the change of the electric current value supplied to a compressor, and a load factor, (c) is a compressor. It is a graph which shows the change of the electric current value supplied.

  Embodiments of the present invention will be described in detail with reference to the drawings as appropriate. In each figure, common portions are denoted by the same reference numerals, and redundant description is omitted.

<Embodiment>
<Configuration of management system>
FIG. 1 is a block diagram showing an outline of a management system according to an embodiment of the present invention. The management system A according to the present invention is a cloud computing system that allows a user to use a service provided by a server group existing on a network without the user being aware of the server group (such as the general management center 1). It has become.

  The management system A includes an overall management center 1, plant bases 21, 22 and 23, a user PC 3 (Personal Computer), a research and development center 4, a service center 5, and an authentication server 6.

The overall management center 1 acquires operation information transmitted from the respective plant bases 21, 22, and 23 through the network N <b> 1, and compressor device information transmitted from the user PC 3, and manages them collectively. . The overall management center 1 provides various information regarding the compressor to the user PC 3 via the network N2.
The overall management center 1 is operated by, for example, a compressor manufacturer or a maintenance company. Details of the overall management center 1 will be described later.

The plant bases 21, 22, and 23 shown in FIG. 1 are provided in different regions, and one or a plurality of compressors are installed in each plant base. Incidentally, the plant bases 21, 22, and 23 are operated by companies and local governments that own the compressors.
The plant base 21 is provided with compressors 211a and 211b, interfaces 212a and 212b, and communication means 213.

The compressor 211a is an oil-free screw compressor, for example, and is driven by the control means 18 (see FIG. 2) according to a preset program.
Incidentally, the control unit 18 transmits operation information of the compressor 211a every moment (for example, every 1 sec) to the overall management center 1 via the communication unit 213 and the network N1. Note that “every moment” may be, for example, every 0.1 sec or every few seconds.
Since the compressor 211b and the interface 212b are the same as described above, the description thereof is omitted. Further, the plant bases 22 and 23 provided in an area different from the plant base 21 are the same as described above, and thus the description thereof is omitted. The configuration and control of each compressor will be described later.

  Information transmitted from the communication means 213, 223, 233 at each plant base is encrypted and transmitted to the central management center 1 via the network N1. Incidentally, the communication unit 101 (see FIG. 4) provided in the overall management center 1 decrypts the encrypted information received from each of the communication units 213, 223, and 233, and uses the information acquired from which compressor. It can be identified whether there is any.

The user PC 3 is provided, for example, in a central management room (not shown) at each plant base, and can communicate with the overall management center 1 via the network N2. Then, by being authenticated by the authentication server 6, various information from the central management center 1 is transmitted to the user PC 3. Incidentally, the “user” is, for example, an administrator of each plant base.
In addition, in FIG. 1 (and FIG. 4), one user PC 3 is illustrated, but actually, a personal computer installed in the central management room of each plant base or a user uses a wireless communication card. There are a plurality of user PCs 3 such as personal computers used in places other than the central management room.

  In the research and development center 4, information stored in each of the storage units 104 to 108 (see FIG. 4) of the overall management center 1 is acquired, and a more advanced management system is researched and developed by analyzing the information. The research and development center 4 updates and upgrades various applications used in the overall management center 1 through the network N3.

The service center 5 includes a service PC 51 and a management PC 52.
The service PC 51 is configured such that, for example, an image displayed on the user PC 3 owned by the user (for example, FIG. 7 (a), FIG. 7A, An image similar to (image shown in (b)) can be displayed.
Then, a service person who operates the service PC 51 contacts the user by using e-mail, telephone, or the like while viewing the image when a compressor failure occurs.

  The management PC 52 is installed in a management room of the service center 5 and can acquire information stored in the storage units 104 to 108 of the overall management center 1 via the network N3 and the communication unit 118 (see FIG. 4). It has become. Note that the administrator of the service center 5 constantly monitors information on each compressor displayed on the monitor of the management PC 52.

  The authentication server 6 verifies the validity of the user by authenticating the user ID, which is unique information regarding the user identifier, and the password corresponding to the user ID. For example, the authentication server 6 performs an authentication process using a public key and a secret key.

<Compressor configuration>
FIG. 2 is a block diagram showing the configuration of the compressor. In the following, the compressor 211a installed in the plant site 21 will be described, but the other compressors 211b, 221, 231 (see FIG. 1) have the same configuration.
The compressor 211 a includes a compressor body 11, an induction motor 12, a cooler 15, an air discharge valve 16, a control unit 18, and an activation panel or inverter panel 19.
The compressor body 11 is, for example, an oil-free screw compressor, and includes a pair of male and female screw rotors (not shown) arranged so that their rotation axes are parallel, and these are casings (not shown). Is housed in.

  A pinion gear (not shown) is installed at the shaft end of the female screw rotor (not shown), and this pinion gear meshes with a helical gear installed on the rotating shaft of the induction motor 12. Further, timing gears (not shown) are respectively attached to the male and female screw rotors, and the male and female screw rotors rotate in synchronization with each other.

The suction side of the compressor body 11 is connected to the suction port via the capacity adjustment valve 13 and the suction filter 14, and the discharge side of the compressor body 11 is connected to the discharge port via the cooler 15. Cooling water supplied from the inlet flows into the cooler 15 through the pipe a5, and after heat exchange with the high-temperature and high-pressure gas discharged from the compressor body 11, flows out from the outlet through the pipe a6. To do.
Further, a discharge valve 16 and a discharge silencer 17 are sequentially connected to a pipe a4 branched from the pipe a3. The discharge valve 16 is opened when an unload operation (no-load operation) described later is performed, and is closed when a load operation (load operation) is performed. The equipment configuration of the compressor may change depending on customer specifications.

A pipe a1 connected to the suction side of the compressor body 11 includes a suction pressure sensor P1 for detecting the pressure of the gas flowing into the compressor body 11, a suction temperature sensor T1 for detecting the temperature of the gas, Is installed.
A discharge pressure sensor P2 that detects the pressure of the gas discharged from the compressor body 11 and cooled by the cooler 15 is detected in the pipe a3 that communicates with the compressor body 11 and the discharge port. The temperature of the gas is detected. A discharge temperature sensor T2 is installed.
A cooling water inflow temperature sensor T3 that detects the temperature of the cooling water flowing into the cooler 15 is installed in the pipe a5, and a cooling water that detects the temperature of the cooling water that flows out of the cooler 15 is installed in the pipe a6. An outflow temperature sensor T4 is installed. Note that the mounting position of each sensor may be changed according to customer specifications.

  Sensor information is input to the control means 18 from each pressure sensor and temperature sensor. That is, operation information (suction pressure, discharge pressure, suction temperature, discharge temperature, current value, etc.) of the compressor 211a is input to the control means 18 every predetermined time (for example, 1 sec). The control means 18 performs overall control of driving of the compressor 211a based on the sensor information and setting information.

  The starter panel or inverter panel 19 converts AC power supplied from an AC power source (not shown) into DC power, and then converts it into three-phase AC power corresponding to a command signal input from the control means 18 for induction. Output to the motor 12. In addition, you may install the starting panel or the inverter panel 19 in the exterior of the compressor 211a.

When three-phase AC power is input from the starter panel or inverter panel 19 according to the command signal output from the control means 18, the induction motor 12 rotates at a predetermined speed. Along with this, a pinion gear (not shown) rotates and a male and female screw rotor (not shown) rotate synchronously. Then, the gas sucked through the suction filter 14 and the capacity adjustment valve 13 is compressed by the compressor main body 11 and discharged as a high-temperature and high-pressure gas, and after being appropriately cooled by the cooler 15, goes to the discharge port. . Incidentally, a load (not shown) driven by compressed gas is connected to the discharge port. Moreover, you may install the control means 18 in the exterior of the compressor 211a.
In the following description, an arbitrary compressor (main body) is simply referred to as “compressor”, and an arbitrary control means is simply referred to as “control means”.

<Load operation / Unload operation>
FIG. 3 is a graph showing changes in the discharge pressure of the compressor. In the compressor 11, a load operation (load operation) and an unload operation (no load operation) are repeatedly executed. When performing the load operation, the control means 18 adjusts the opening degree of the capacity adjustment valve 13 while driving the compressor 11 and closes the air discharge valve 16. Then, the high-temperature and high-pressure gas discharged from the compressor 11 goes to the discharge port via the pipe a2, the cooler 15, and the pipe a3. During the load operation, the discharge pressure of the compressor 11 often increases.

It is assumed that the target discharge pressure P _α , the unload pressure P _β (> P _α ), and the load pressure P _γ (<P _α ) of the compressor 11 shown in FIG. 3 are set in advance. Incidentally, the discharge pressure of the compressor 11 is detected by a discharge pressure sensor P2 (see FIG. 2) and input to the control means 18.

When the discharge pressure of the compressor 11 becomes equal to or higher than the unload pressure P _beta, the control unit 18 opens the blow-off valve 16 while driving the compressor 11, to perform the unloading operation. As a result, the gas discharged from the compressor 11 is diverted also to the air discharge valve 16 side via the pipe a4, and is discharged outside the system via the air discharge port. As described above, in the unload operation, the discharge pressure is gradually lowered because a part of the high-pressure gas is released out of the system by opening the discharge valve 16. Incidentally, even when the unloading operation is performed, by continuing to drive the induction motor 12, unnecessary on / off is eliminated and high energy efficiency is maintained.

Thereafter, when the discharge pressure of the compressor 11 becomes equal to or lower than the load pressure _Pγ , the control means 18 switches to the load operation again and increases the discharge pressure. In this way, the discharge pressure P of the compressor 11 has to be changed within a predetermined range which sandwich the target discharge pressure P _alpha (load pressure P _gamma ≦ P ≦ unload pressure P _beta).
By the way, when unloading is performed, high-pressure gas is released to the outside of the system, resulting in energy loss. Therefore, the operation efficiency of the compressor 11 becomes higher as the time for performing the unload operation is shorter.

<General management center configuration>
FIG. 4 is a block diagram showing the configuration of the overall management center. As shown in FIG. 4, the overall management center 1 includes a communication unit 101, a first information management unit 102, various storage units 104 to 108, an information processing unit 109, a front server 115, and a second information management unit. 116.

The communication unit 101 decrypts the encrypted information received from the communication units 213, 223, and 233 (see FIG. 1) installed at the plant bases 21, 22, and 23, respectively.
The first information management unit 102 includes a first information acquisition unit 102a and a first information disclosure unit 102b.

The first information acquisition unit 102a transmits a command signal for acquiring operation information to the control unit 18 of the compressor 11 via the communication unit 101 and the network N1 every predetermined time (for example, 1 sec). And the 1st information acquisition part 102a acquires the operation information transmitted from the control means 18 momentarily according to the said command signal via the network N1, the communication means 101, and F / W114a, and the compressor 11 And stored in the operation information storage means 104.
When receiving a command signal for acquiring information related to the compressor 11 from the user PC 3, the first information disclosing unit 102b reads operation information corresponding to the command signal from the storage units 104 to 107, and communicates with the communication unit 112 and the network N2. Is transmitted to the user PC 3 via.

The F / W (Firewall) 103 fulfills a security function for preventing data stored in the storage units 104 to 108 of the central management center 1 from being illegally acquired by a third party.
The operation information storage means 104 stores the operation information of the compressor 11 in a database format. The “operation information” includes command information (such as an unload operation command / load operation command) output from the control unit 18 to the compressor 11 and sensor information detected by various sensors. Further, the operation information transmitted from the control means 18 to the general management center 1 is attached with identification information of each compressor 11.

  The setting information storage unit 105 stores setting information of the compressor 11 in a database format. Incidentally, the setting information of the compressor 11 is acquired every predetermined period by the first information acquisition unit 102a, and stored in the setting information storage unit 105 in association with the identification information of the compressor 11.

The failure / maintenance information storage means 106 stores the failure information and maintenance information of the compressor 11 in a database format. The “failure information” is, for example, when the discharge temperature of the compressor 11 is out of a preset temperature range or when the discharge pressure of the compressor 11 is lower than the load lower limit pressure. Is output from.
In addition, “maintenance information” is input from the information terminal 7 (see FIG. 8) during repair or inspection work by an operator.

The operation information storage unit 107 stores operation information such as the operation time and the number of operations of the compressor 11 in a database format. Incidentally, the “operation time” includes the load operation time, the unload operation time, and the stop time of the compressor 11. Further, the “number of operations” includes the number of unloads of the compressor 11 and the number of times the power is turned on / off.
Such information can be obtained by the information processing unit 109 reading and calculating the operation information stored in the operation information storage unit 104.

The equipment information storage means 108 stores the plant base name, base code, compressor name, compressor code, and the like in a database format.
Further, the device information storage means 108 includes the device name, device code, model, usage time, service life time, previous inspection date, inspection result, previous replacement date, next replacement scheduled date, inventory of the devices constituting the compressor 11. Numbers are stored in database format.
Incidentally, the device name, device code, and model are transmitted from the user PC 3 to the central management center 1 via the network N2 in advance, and are associated with each compressor 11 by the second information acquisition unit 116a. Stored in the storage means 108.

The information processing unit 109 includes electronic circuits such as a CPU (Central Processing Unit), a ROM (Read Only Memory), a RAM (Random Access Memory), and various interfaces. The information processing unit 109 performs various processes based on the set program.
Details of processing performed by the information processing unit 109 will be described later.

The bus 111 is connected to the first information management unit 102, the second information management unit 116, the storage units 104 to 108, the information processing unit 109, and the F / W 117, and enables the exchange of information described above.
The communication unit 112 is a communication line for transmitting and receiving information between the user PC 3 and the authentication server 6 and the central management center 1 via the network N2. After the authenticity of the user is confirmed by the authentication server 6, the communication unit 112 transmits / receives information to / from the front server 115 via the communication line corresponding to the user ID and the F / W 114b.

The F / Ws 114a and 114b have a security function for preventing a third party from entering the central management center 1 from the outside and acquiring data illegally.
The front server 115 outputs the user ID to the first information disclosure unit 102b and the second information disclosure unit 116b when the authentication process by the authentication server 6 is completed. Incidentally, the user ID is associated with one or a plurality of plant bases at the time of registration. In addition, when the user who has viewed the image displayed on the monitor of the user PC 3 makes a predetermined selection using an input unit (not shown), the front server 115 displays the selection information in the first information disclosure unit 102b. Or it outputs to the 2nd information disclosure part 116b.
Information provided to the user PC 3 will be described later.

The second information management unit 116 includes a second information acquisition unit 116a and a second information disclosure unit 116b.
The second information acquisition unit 116a acquires device information from the user PC 3 via the network N2 and the communication unit 112, and stores the device information in the device information storage unit 108 for each compressor 11.
When the second information disclosure unit 116b receives a command signal for acquiring device information from the user PC3 of the user, the second information disclosure unit 116b reads the device information from the device information storage unit 108 in accordance with the command signal, and the user information via the communication unit 112 and the network N2 Send to PC3.

The F / W 117 has a security function for preventing a third party from entering the central management center 1 from the outside and acquiring data illegally.
The communication means 118 is a communication line for communicating with the research and development center 4 via the network N3.

<Processing of information disclosure service>
Below, the case where the information regarding the compressor installed in the plant base 21 is acquired and disclosed as an example is demonstrated.

(1. Operation information)
FIG. 5 is a sequence showing an operation related to the operation information acquisition / disclosure process.
In step S101, the first information acquisition unit 102a (see FIG. 4) sends the operation information to the control unit 18 (see FIG. 2) of the compressor 11 via the communication unit 101, the network N1, and the communication unit 213 (see FIG. 1). A transmission command signal is transmitted. Next, in step S102, the control unit 18 transmits operation information corresponding to the operation information transmission command to the first information acquisition unit 102a. The contents of the operation information have been described above and will not be described.

In step S <b> 103, the first information acquisition unit 102 a stores the operation information of the compressor 11 received from the control unit 18 in the operation information storage unit 104. The processes in steps S101 to S103 described above are repeatedly executed every predetermined time (for example, 1.0 sec).
Note that the process of step S101 may be omitted, and the control unit 18 may automatically transmit the operation information to the first information acquisition unit 102a.

  The user who manages the plant site 21 in step S104 of FIG. 5 operates an input unit (not shown) of the user PC 3 to access a compressor remote monitoring service site provided by the overall management center 1. Then, for example, a login screen G1 as shown in FIG. 6A is displayed on the monitor of the user PC 3.

The user operates the input unit of the user PC 3, inputs the user ID in the user ID column G101, inputs the password in the password column G102, and clicks the login button G103. As a result, the user ID and password are transmitted to the authentication server 6 via the network N2.
Next, in step S105, the authentication server 6 performs the authentication process described above. Upon confirming the validity of the user, the authentication server 6 displays a screen G2 shown in FIG. 6B on the monitor of the user PC 3.

The “facility monitoring service” illustrated in FIG. 6B is a service that allows the user to view compressor operation information, setting information, failure / maintenance information, or operation information.
Further, the “maintenance management service” shown in FIG. 6B is a service that allows the user to view the device information of the compressor.

When browsing the operation information of the compressor 11, the user selects the “facility monitoring service” G201 shown in FIG. By this operation, an operation information acquisition command signal is transmitted from the user PC 3 to the first information disclosure unit 102b in step S106 of FIG.
Next, in step S107, the first information disclosure unit 102b searches the operation information stored in the operation information storage unit 104 for the operation information of the plant site corresponding to the user ID, and acquires the operation information. (Step S108). In step S109, the first information disclosure unit 102b transmits the acquired operation information to the user PC 3.

  Then, the operation information screen G3 shown in FIG. 7A is displayed on the monitor of the user PC 3. The name of the plant base (plant base 1) is displayed in the code G301 shown in FIG. Further, by pulling down “compressor No” in the code G302, the user can select a compressor (for example, compressor No. 1) that the user wants to browse.

In the example shown in FIG. 7A, it can be seen that the suction pressure of the compressor 11 is PPP1 kPa and the suction temperature is TTT1 ° C. (when the user accesses the site of the central management center 1).
It should be noted that it is preferable that the information shown in FIG. 7A is displayed next to the configuration diagram of the compressor shown in FIG.

(2. Setting information)
The sequence of the setting information related to the compressor 11 is the same as the above-described operation information sequence (see FIG. 5), and the description thereof is omitted.
When the user's validity is authenticated and the user browses the setting information, for example, a setting information screen G4 shown in FIG. 7B is displayed on the user PC 3. In FIG. 7B, as the “set pressure”, unload pressure: 880 kPa, load pressure: 830 kPa, load lower limit pressure: 400 kPa, and target pressure: 860 kPa are displayed.

  Incidentally, the “load lower limit pressure” is a lower limit value allowed as the discharge pressure of the compressor 11. When the discharge pressure detected by the discharge pressure sensor P2 (see FIG. 2) falls below the load lower limit pressure, the control unit 18 transmits failure information to the overall management center 1 while continuing to drive the compressor 11.

(3. Failure / maintenance information)
FIG. 8 is a sequence showing an operation related to acquisition / publication processing of failure / maintenance information.
In step S201, the first information acquisition unit 102a (see FIG. 4) transmits a failure information transmission command signal to the control unit 18 (see FIG. 2) via the communication unit 101 and the network N1. In step S <b> 202, when a failure corresponding to the command occurs within a predetermined time, the control unit 18 transmits the failure to the first information acquisition unit 102 a in association with the identification information of the compressor 11. Next, in step S <b> 203, the first information acquisition unit 102 a stores the failure information in the failure / maintenance information storage unit 106.

  Next, in step S204, the first information acquisition unit 102a transmits the failure information received from the control means 18 to the management PC 52 (see FIG. 1). Thereby, the administrator of the service center 5 (see FIG. 1) can know the failure at substantially the same timing as the failure has occurred at the site where the compressor 11 is installed. Accordingly, the service staff of the service center 5 can promptly contact the user at the plant base where the failure has occurred using e-mail or telephone.

Next, in step S <b> 205, the management PC 52 transmits the failure information described above to the information terminal 7. The information terminal 7 is, for example, an information terminal possessed by a worker of the service center 5 (located in the vicinity of the plant base where the failure has occurred). The processes of steps S201 to S205 described above are repeated at predetermined time intervals (or triggered by detection of the occurrence of a failure).
Note that the processing in step S201 may be omitted, and failure information may be automatically transmitted from the control unit 18 to the first information acquisition unit 102a when a failure occurs.

Next, in step S206, maintenance information is stored in the storage means (not shown) of the information terminal 7 by the worker who repaired (or checked) the failure. In step S207, the information terminal 7 transmits maintenance information to the first information acquisition unit 102a, triggered by pressing of the transmission button by the worker. The maintenance information includes identification information of the compressor 11 that is a maintenance target, time information, maintenance contents, and maintenance results.
Next, in step S208, the first information acquisition unit 102a stores the maintenance information received from the information terminal 7 in the failure / maintenance information storage unit 106 in association with the failure information transmitted in step S204.
Note that each piece of information described above is also stored in the device information storage unit 108 corresponding to the devices that make up the compressor 11.

Next, in step S209 in FIG. 9, the user PC 3 transmits the user ID and password to the authentication server 6 via the network N2, and in step S210, the authentication server 6 transmits the authentication result to the user PC 3. After being authenticated by the authentication server 6, in step S211, the user PC 3 transmits a failure / maintenance information acquisition command signal to the first information disclosure unit 102b.
Next, in step S212, the first information disclosure unit 102b searches for and acquires failure / maintenance information at the plant site corresponding to the user ID from the failure / maintenance information storage unit 106 (step S213). Next, in step S214, the first information disclosure unit 102b transmits failure / maintenance information to the user PC 3.

Then, the failure / maintenance information screen G8 shown in FIG. 10 is displayed on the monitor of the user PC 3. The failure / maintenance information screen G8 displays failure / maintenance information up to the time when the user accesses the compressor remote monitoring service site (or the month specified by the user).
In the example shown in FIG. 10A, the occurrence date and time, the message, and the recovery time are displayed in order from the left. For example, referring to the display screen G8, it can be seen that a sensor failure occurred at 18:00 on April 1, 2012, and the recovery occurred at 18:30 on the same day.

Then, when the user clicks the “sensor abnormality” column via the input means (not shown), for example, a failure information screen G9 shown in FIG. 10B is displayed. In this example, an abnormality occurs in the suction temperature sensor T1 (see FIG. 2). At that time, the compressor 11 and the main motor (induction motor 12) stop, APC (Active Power Control) setting, PSC (Power Save Control) Settings and ASS (Auto Start & Stop) settings are temporarily disabled. The details of APC, PSC, and ASS are not described here.
In this way, the user can easily browse the failure / maintenance information of the compressor 11 by accessing the integrated management center 1 via the network N2.

(4. Operation information)
FIG. 11 is a sequence showing operations related to the acquisition / publication processing of the operation information.
In step S301, the information processing unit 109 retrieves the operation information of the compressor 11 from the operation information storage unit 104, and acquires predetermined operation information (step S302). Next, in step S303, the information processing unit 109 calculates the operation time and the number of operations based on the acquired operation information.
As described above, the “operation time” is, for example, the load operation time, unload operation time, and stop time of the compressor 11. The “number of operations” is, for example, the number of unloads or ON / OFF of the compressor 11.

In addition, the operation information includes the service life of the compressor 11 and the previous replacement date. The service life time of the compressor 11 and the previous replacement date are input via the information terminal 7 (see FIG. 8) by, for example, an operator who replaces or inspects parts of the compressor 11.
In step S <b> 304, the information processing unit 109 calculates the operation time / number of times (that is, operation information) for each compressor 11 and stores the operation time / number of operations in the operation information storage unit 107.

In step S305, the user PC 3 transmits the user ID and password to the authentication server 6 via the network N2, and the authentication server 6 performs authentication processing in step S306.
After the authentication process is completed, the user selects “view operation information” of the compressor 11. With this operation, an operation information acquisition command signal is transmitted from the user PC 3 to the first information disclosure unit 102b in step S307.

  Next, in step S308, the first information disclosure unit 102b searches the operation information storage unit 107 for the operation information of the plant base corresponding to the user ID, and acquires the operation information (step S309). Further, in step S310, the first information disclosure unit 102b transmits the operation information to the user PC 3. Then, for example, the operation information screen shown in FIGS. 12A to 12C is displayed on the monitor of the user PC 3.

FIG. 12A is a screen display example showing the transition of the unload time. The horizontal axis of FIG. 12A indicates the date (as of April 2012), and the vertical axis indicates the total time of unload operation for each date (unload time). By browsing the screen G5, the user can easily grasp the transition of the unload time. Note that the transition of unloading time in months or the transition of unloading time in years may be displayed.
Further, the unload time or the cumulative value of the number of unloads from the installation of the compressor 11 to a predetermined date and time may be displayed on the user PC 3.

  FIG. 12B is a screen display example showing the transition of the number of unloads. The horizontal axis of FIG. 12B indicates the date (as of April 2012), and the vertical axis indicates the number of times of switching from the load operation to the unload operation (the number of unloads). The user can easily grasp the transition of the number of unloads for each date by browsing the screen G6 shown in FIG.

FIG.12 (c) is a screen display example which shows the change of the discharge pressure of a compressor. The horizontal axis of FIG. 12C indicates the time (as of April 1, 2012), and the vertical axis indicates the discharge pressure of the compressor 11.
When browsing the history of the operating state of the compressor 11, the user selects “browsing operation information” (not shown) on the selection screen, and further, “discharge pressure” (not shown) on a specific date in a pull-down menu or the like. To select).
Thereby, the user can easily grasp the operating state of the compressor 11 at the past specific date and time. Incidentally, FIG. 12C shows the change in the discharge pressure on a specific date. For example, the average value of the discharge pressure on a monthly basis may be displayed, or the change in the discharge temperature may be displayed. Also good.

(5. Device information)
Next, the maintenance management service among the compressor monitoring services will be described. FIG. 13 is a sequence showing operations related to device information acquisition / publication processing.
In step S401, the user PC 3 transmits the user ID and password to the authentication server 6 via the network N2, and in step S402, the authentication server 6 performs an authentication process. Then, a screen G2 shown in FIG. 6B is displayed on the monitor of the user PC 3.

Furthermore, when the “maintenance management service” G202 shown in FIG. 6B is selected by the user, the screen transitions to a screen (not shown) to which device information can be attached. The user designates a specific compressor 11 and attaches information such as a device name, a device code, a model, a previous replacement date, and an inventory number of the designated compressor 11 to the central management center 1 by attaching it in a file format, for example. Transmit (step S403).
This process is performed when an administrator at each plant site performs a compressor remote monitoring service registration process or update process.

  Next, in step S403, the user PC 3 transmits device information to the second information acquisition unit 116a. Next, in step S404, the second information acquisition unit 116a stores the received device information in the device information storage unit 108 in association with the compressor 11 selected by the user.

  Further, when the user wants to browse the device information of the plant base managed by the user, the user accesses the integrated management center 1 by operating the user PC 3. That is, in step S405 in FIG. 13, the user PC 3 transmits the user ID and password to the authentication server 6 via the network N2, and the authentication server 6 performs an authentication process in step S406.

  Next, in step S407, the user PC 3 transmits a device information acquisition command signal to the second information disclosure unit 116b. In addition, when the some compressor 11 exists in a plant base, a user selects the specific compressor 11 via an input means among the several compressors displayed on the screen (not shown) of user PC3. .

Next, in step S408, the second information disclosure unit 116b searches for and acquires device information related to the compressor 11 designated by the user from the device information stored in the device information storage unit 108 (step S409). .
Next, in step S410, the second information disclosure unit 116b transmits the device information to the user PC 3. As a result, a device information screen (not shown) is displayed on the monitor of the user PC 3.
The device information screen displays the device name, device code, model, accumulated usage time, lifetime usage time, failure history, previous replacement date, next replacement date, inventory quantity, and the like.

<Analysis process of driving tendency>
(A. Change of set value)
As described above, the target discharge pressure P _α of the compressor 11 is set in advance, and the control means 18 determines that the discharge valve 16 (see FIG. 2) when the discharge pressure becomes equal to or higher than the unload pressure P _β (> P _α ). Open the valve to switch to unload operation (no-load operation). Further, the control means 18, when the discharge pressure falls below the load pressure P _gamma, switches the load operation by closing the blow-off valve 16 (load operation). Incidentally, since the compressed air is discharged out of the system in the unload operation, the energy efficiency of the compressor 11 increases as the time (ratio) for the unload operation decreases.
Therefore, the setting of the unload pressure _P β has a significant impact on the energy efficiency of the compressor 11.

The information processing unit 109 performs, for example, the following processing when the user watching the monitor of the user PC 3 selects “energy saving operation” (not shown) via the input unit (not shown). To do.
That is, the information processing unit 109 reads the operation information of the compressor 11 corresponding to the user ID from the operation storage unit 104. The operation information storage unit 104 stores information indicating which of the load operation and the no-load operation has been executed in the compressor 11 in association with the identification information and time information of the compressor 11.

Then, the information processing means 109 determines whether the proportion of unloading time is equal to or greater than a predetermined value (or is the number of unloads equal to or greater than a predetermined number) as the operation tendency of the compressor 11 during a preset predetermined period. Determine whether or not.
For example, when the proportion of the unload time is greater than or equal to a predetermined value, the information processing unit 109 analyzes the operation information of the compressor 11 for the unload pressure that makes the proportion of the unload time less than the predetermined value. To calculate. In the analysis process, the behavior of the compressor 11 is simulated once or a plurality of times using the device information (specification information) stored in the device information storage means 108, and the proportion of the unload time in the simulation result is A method of selecting the smallest one as the unload pressure may be used. Further, the unload pressure may be determined by other methods (statistical method, learning process, etc.) using the operation information of the compressor 11. Then, the information processing unit 109 transmits the determined unload pressure to the user PC 3 corresponding to the compressor 11 via the network N2.
Incidentally, setting values other than the unload pressure can be presented to the user in the same manner as described above.

Further, a set value such as an unload pressure may be determined based on a load factor of the compressor 11 (a ratio of unload time within a predetermined time) and transmitted to the user PC 3. In this case, the information processing unit 109 calculates the load factor based on the current value supplied to the compressor 11 during a predetermined period, and stores it in the operation information storage unit 104 in association with the identification information of the compressor 11. Then, when the average value of the load factor is lower than the predetermined value, the information processing means 109 determines a set value for setting the load factor to be equal to or higher than the predetermined value by the operation information analysis process, and the compressor 11 via the network N2. To the user PC 3 corresponding to.
In addition, various methods, such as a simulation, a statistical method, and a learning process, can be used for the above-mentioned analysis process. Also, setting values other than the unload pressure can be presented to the user in the same manner as described above.

  Alternatively, the operation information of another compressor 11 stored in the operation information storage unit 104 may be searched, and the set value may be determined based on the search result. In this case, the information processing unit 109 searches the device information storage unit 108 for a predetermined number (for example, 100) of the compressors 11 having the same device name, device code, and model as the compressor 11 managed by the user. Then, the information processing means 109 searches for a compressor that is close to the operating condition of the compressor 11 of the user among the plurality of compressors 11 to be compared.

  Further, the information processing unit 109 searches for the compressor 11 having the shortest unload time (or the shortest unload number) from among the narrowed down compressors 11 having the number of failures equal to or less than a predetermined value. . Then, the information processing unit 109 transmits the unload pressure of the compressor 11 to the user PC 3 via the network N2.

When the value of the unload pressure is set as the unload pressure of the compressor 11 managed by the user, the unload time is likely to be shorter than before, and the operation efficiency of the compressor 11 can be increased.
Note that set values other than the unload pressure can be presented to the user in the same manner as described above.

(B. Proposal for the next replacement)
FIG. 14A is a graph showing temporal changes in discharge pressures of a plurality of compressors. The first compressor (target discharge pressure P _A ) is driven at times t1 to t2 and t3 to t4 shown in FIG. 14 (a), and the second compressor (target discharge pressure P at time t2 to t3). _B > P _A ) is driven.
That is, in FIG. 14A, two compressors 11 having different target discharge pressures are alternately driven every predetermined time. Incidentally, alternately driving the two compressors 11 in this way is transmitted from the user PC 3 to the general management center 1 at the time of registration or update of the compressor remote monitoring service, for example, and stored in the setting information storage means 105. The

For example, when creating information to be provided to the user regarding the compressor 11, the information processing unit 109 performs the following processing.
That is, when the average value of the discharge pressure is greater than the target discharge pressure by a predetermined value or more as the operating tendency of the compressor 11 during the predetermined period, the information processing unit 109 sets the discharge pressure to the target discharge pressure. Search for the nearest compressor candidate (one or more) from the device information storage means 108.
Incidentally, in the device information storage means 108, in addition to the information related to the compressor 11 of each user, specification information of all the compressors 11 that can be handled by the service center 5 is stored.

The information processing unit 109 transmits the search result to the user PC 3 via the network N2.
The information processing unit 109 may present to the user a combination that is cheaper than the total price of the compressor 11 (the first compressor and the second compressor) that the user currently owns from among the search results. . As a result, when the user purchases a new compressor, the user can select a compressor that is lower in price than the currently operating compressor 11 and satisfies the conditions required by the user (such as target discharge pressure).

FIG. 14B shows a graph (upper) showing changes in the current value supplied to the compressor and a graph (lower) showing changes in the load factor of the compressor. The operation information stored in the operation information storage unit 104 includes a current value supplied to the compressor 11.
Also, of the change in the current value shown on the FIG. 14 (b), the current value I _A corresponds to the load operation, the current value I _B corresponds to the unload operation. Further, the load factor shown at the bottom of FIG. 14B is a ratio of the unload time when the predetermined time is used as a reference (100%), and is sequentially calculated every predetermined time.

For example, when creating information to be provided to the user regarding the compressor 11, the information processing unit 109 performs the following processing.
That is, the information processing unit 109 reads the current value of the target compressor 11 and calculates the load factor for a predetermined period based on the current value. And the information processing means 109 determines whether the average value of the load factor in a predetermined period is lower than a predetermined value as an operation tendency of the compressor 11. When the average value of the load factor is lower than the predetermined value, the information processing unit 109 compresses the load factor to a predetermined value or more based on the operation information of the other compressor 11 stored in the operation information storage unit 104. Determine candidates.

Note that the information processing unit 109 selects one or a plurality of compressor candidates from the compressors 11 operating under the same conditions (for example, target discharge pressure) as the target compressor 11.
Thus, when a user who manages the compressor 11 replaces the compressor, a compressor having a higher load factor (that is, higher operating efficiency) than the currently operating compressor 11 is selected as a plurality of compressor candidates. You can choose from.

(C. Abnormal sign determination processing)
Further, the information processing unit 109 of the overall management center 1 determines the presence / absence of an abnormality sign of the compressor 11 based on the operation information stored in the operation information storage unit 104. That is, the information processing unit 109 determines whether or not there is a sign of abnormality in the compressor 11 based on, for example, the rate of change of at least one of the suction temperature and the discharge temperature as the operating tendency of the compressor 11 during a predetermined period.

For example, the information processing unit 109 calculates the average change rate (increase rate) of the discharge temperature of the compressor 11 throughout the year, and determines that there is an abnormal sign when the average change rate is equal to or greater than a predetermined value.
Then, the information processing unit 109 transmits information related to the abnormality sign to the user PC 3 corresponding to the compressor 11 via the network N2.

Further, for example, an allowable range of the suction temperature (or discharge temperature) of the compressor 11 is set in advance, and the compressor 11 is based on the average rate of change of the actual suction temperature (or discharge temperature) of the compressor 11 in a predetermined period. May be predicted and transmitted to the user PC 3.
Thus, the user can easily know the presence / absence of an abnormality sign and the timing of occurrence of an abnormality in the compressor 11 managed by the user.
In addition, instead of the suction temperature / discharge temperature of the compressor 11, the presence / absence of an abnormality sign is determined based on other operation information such as the suction pressure, discharge pressure, or current value supplied to the compressor 11. May be. Moreover, you may determine combining these suitably.

(D. Alert for maintenance)
FIG. 14C is a graph showing a change in the current value supplied to the compressor. Note that the current value I _C shown in FIG. 14 (c) corresponds to the load operation, the current value I _D corresponds to the unload operation.
Meanwhile, the compressor 11, if the duration of the unload operation has exceeded a predetermined value Delta] t _0, automatically shutting down (i.e., stops the driving of the induction motor 12) there is. As a result, energy-saving operation can be performed, but if the compressor 11 is stopped for a long time, a malfunction may occur at the next start-up.

Therefore, the information processing unit 109 refers to the operation information storage unit 104, and when there is a compressor 11 whose stop period is equal to or longer than a predetermined period, the information processing unit 109 sends a compressor to the user PC 3 corresponding to the compressor 11 via the network N2. 11 urge information for maintenance.
The operation stop period of the compressor 11 is, for example, when the first information acquisition unit 102a acquires operation information, when the stop state of the compressor 11 is detected, the counter value is incremented. This can be grasped by storing it in the operation information storage means 104 in association with the identification information.

The information processing unit 109 refers to the operation information storage unit 104 and transmits information that prompts maintenance of the compressor 11 to the user PC 3 when the value of the counter indicating the stop period of the compressor 11 is equal to or greater than a predetermined value.
Accordingly, the user who manages the compressor 11 can easily grasp that the compressor 11 managed by the user has been stopped for a long time and maintenance is necessary.

(E. Calculation of parts replacement date)
As described above, the operation information storage means 107 of the central management center 1 stores the lifetime usage time and the previous replacement date of the devices (parts) constituting the compressor 11. The information processing unit 109 calculates the accumulated usage time for each device based on the operation information stored in the operation information storage unit 104. Here, “cumulative usage time” means a cumulative value of usage time up to the present (when the cumulative time is calculated) when the previous replacement date is used as a reference for a specific device.

Then, the information processing unit 109 calculates the next scheduled replacement date for each device based on the accumulated usage time, the lifetime usage time read from the operation information storage unit 107, and the previous replacement date, and the target device Are stored in the operation information storage means 107 in association with the identification information.
The information processing unit 109 calculates the period until the lifetime usage time is reached based on the increase rate of the cumulative usage time, and determines the “next replacement scheduled date” as the date when the period has elapsed from the previous replacement date. To do.

Then, when the next scheduled replacement date approaches (for example, one month before), the information processing unit 109 transmits information on the next scheduled replacement date to the user PC 3 via the network N2.
As a result, the user can easily grasp the scheduled replacement date of each component constituting the compressor 11. Therefore, the user's management burden is reduced.

<Effect>
According to the machine facility management system A according to the present embodiment, what a user should prepare is only a minimum connection environment (user PC 3, mobile terminal, browser, communication means, etc.), and management of each compressor 11 is performed. The central management center 1 can perform all the operations at once. Therefore, the operation information and device information of the compressor 11 can be provided to the user without greatly changing the existing compressor 11 at each plant base.

In the management system A according to the present embodiment, information related to the compressor 11 at each plant site is stored in each storage unit 104 to 109 of the overall management center 1. Therefore, it is not necessary to install a large-capacity storage device at each plant base, and the cost at each plant base can be suppressed.
In addition, the user is given an ID and password corresponding to the plant base that he / she has registered, and can connect to a cloud computing network and grasp the status of the compressor 11 in real time as long as there is an internet connection environment.

Moreover, in this embodiment, based on the operation information of the other compressor 11, setting values (unload pressure etc.) are determined so that the ratio which the unload operation of the compressor 11 accounts may become smaller than predetermined value, The data is transmitted to the user PC 3 via the network N2.
Thus, the compressor 11 performing stable energy saving operation can be searched using the enormous amount of data stored in the storage means 104 to 108, and the set value can be presented to the user.
Therefore, the user can change the set value of the compressor 11 to an appropriate value within the design range based on the presented information. That is, an allowable range in which the set value of the compressor 11 can be changed is set in advance, and a more appropriate set value can be presented to the user within the range.

Further, in the present embodiment, when the average value of the discharge pressure of the compressor 11 is larger than the target discharge pressure by a predetermined value or more, a compressor candidate that brings the discharge pressure close to the target discharge pressure is searched from the device information storage unit 108, The data is transmitted to the user PC 3 via the network N2.
If the average value of the load factor of the compressor 11 is lower than a predetermined value, a compressor candidate having a load factor equal to or higher than the predetermined value is searched from the device information storage means 108 and transmitted to the user PC 3 via the network N2. To do.
As a result, when the compressor 11 is replaced next time, the user can select one or a plurality of compressor candidates that can perform an energy saving operation as compared with the currently operating compressor 11.

In the present embodiment, the presence / absence of an abnormality sign of the compressor 11 is determined based on the rate of change of at least one of the suction temperature and the discharge temperature, and is transmitted to the user PC 3 via the network N2.
In order to detect an abnormal sign related to the compressor 11, it is necessary to grasp the long-term transition of the operation information. When an individual user purchases a computer that stores and processes such an enormous amount of data, it is very expensive. In this embodiment, since the operation information and the like of the compressor 11 are managed by the overall management center 1, the processing burden on the user can be reduced and the cost for managing the compressor 11 can be reduced.

  In the present embodiment, when the stop period is equal to or longer than the predetermined period, information that prompts maintenance of the compressor 11 is transmitted to the user PC 3 via the network N2. Therefore, the compressor 11 can be prevented from malfunctioning at the next start by being stopped for a long period of time, and the user can examine the execution or request of maintenance at an early stage.

In addition, when the life of the compressor 11 comes to an end or for replacement due to a failure, it is necessary to secure an inventory of equipment (parts) constituting the compressor 11 in advance at the plant base. Conventionally, since the life of a device changes depending on the type of device, operation history, failure content, etc., it has been necessary to allow a certain margin in the number of stocks.
On the other hand, in the present embodiment, device information of the compressor 11 is collectively managed using a cloud computing system. For example, when it is necessary to replace the devices constituting the compressor 11, the information is transmitted from the overall management center 1 (or service center 5) to the user PC 3. Therefore, the user's management burden required for maintenance of the compressor 11 and parts replacement can be greatly reduced.

≪Modification≫
In the embodiment, the oil-free screw compressor has been described as an example, but the present invention is not limited to this. That is, the present invention can be applied to other types of compressors (turbo type, vane type, diaphragm type, etc.). Moreover, although the said embodiment demonstrated the case where the management object by the comprehensive management center 1 was a compressor, it is not restricted to this. For example, other types of mechanical equipment such as a power plant, a nuclear power plant, and a water treatment plant can be managed.
In addition to the case where the overall type managed by the overall management center 1 is a single type (for example, only a compressor), a plurality of types of mechanical equipment may be managed. In this case, an identification symbol indicating the type of mechanical equipment is added to the operation information.

Moreover, although the said embodiment demonstrated the case where the authentication server 6 was installed outside the integrated management center 1, it is not restricted to this. That is, an authentication server may be provided in the overall management center 1.
In the above embodiment, the case where the overall management center 1 acquires operation information such as the suction / discharge pressure and the suction / discharge temperature of the compressor 11 has been described. However, the present invention is not limited to this. That is, information related to the ambient temperature and vibration of the compressor 11 may be added to the operation information.
Moreover, although the said embodiment demonstrated the case where the information processing means 109 of the management center 1 performed the analysis process of the driving | running tendency of the compressor 11, it does not restrict to this. For example, the analysis process may be executed by the research and development center 4 and the analysis result may be disclosed from the service center 5 to the user PC 3.

A management system 1 general management center 102a first information acquisition unit 102b first information disclosure unit 104 operation information storage unit (storage unit)
105 Setting information storage means (storage means)
106 Failure / maintenance information storage means (storage means)
107 Operation information storage means (storage means)
108 Device information storage means (storage means)
109 Information processing unit 116 Second information management unit 116a Second information acquisition unit 116b Second information disclosure unit 11, 211a, 211b, 221, 231 Compressor (mechanical equipment)
3 User PC (computer)
N1, N2, N3 Network 16 Ventilation valve 18 Control means

Claims (7)

Operation information storage means for acquiring operation information of one or a plurality of machine equipment every moment via a network, and storing the operation information in association with the identification information of the machine equipment;
Based on the operation information read from the operation information storage unit, the operation tendency of the machine equipment in a predetermined period is analyzed, and the analysis result is stored in the operation information storage unit in association with the identification information of the machine facility. And a mechanical equipment management system. The mechanical facility is a compressor,
The operation information includes information indicating whether a load operation or a no-load operation is performed in the compressor,
The information processing means, as the operation tendency of the compressor during a predetermined period, when the proportion of no-load operation is greater than or equal to a predetermined value, a setting value that makes the proportion of no-load operation less than the predetermined value The machine equipment management system according to claim 1, wherein the system is determined based on an analysis of information and transmitted to a user computer corresponding to the compressor via a network. The mechanical facility is a compressor,
A specification information storage means for storing the specification information of the compressor;
The operation information includes a discharge pressure of the compressor,
When the average value of the discharge pressure is larger than the target discharge pressure by a predetermined value or more as the operation tendency of the compressor during the predetermined period, the information processing means is a compressor whose discharge pressure is closer to the target discharge pressure than the compressor. The machine facility management system according to claim 1 or 2, wherein candidates are searched from the specification information storage means and transmitted to a user computer corresponding to the compressor via a network. The mechanical facility is a compressor,
The operation information includes a current value supplied to the compressor,
When the average value of the load factor calculated based on the current value is lower than a predetermined value as the operating tendency of the compressor during a predetermined period, the information processing means sets the load factor to be equal to or higher than the predetermined value. The machine equipment according to any one of claims 1 to 3, wherein: is determined based on an analysis of the operation information, and is transmitted to a computer of a user corresponding to the compressor via a network. Management system. The mechanical facility is a compressor,
The operation information includes a suction temperature and a discharge temperature of the compressor,
When the rate of increase of at least one of the suction temperature and the discharge temperature is equal to or higher than a predetermined value as the operating tendency of the compressor during a predetermined period, the information processing means determines that there is an abnormal sign in the compressor, The machine equipment management system according to any one of claims 1 to 4, wherein the system is transmitted to a computer of a user corresponding to the compressor. The mechanical facility is a compressor,
The operation information includes a compressor stop period,
When the stop period is equal to or longer than a predetermined period as the operation tendency of the compressor, the information processing means transmits information for urging maintenance of the compressor to a user computer corresponding to the compressor via a network. The machine equipment management system according to any one of claims 1 to 5, wherein: The mechanical facility is a compressor,
Information stored in the storage means of the operation information includes the lifetime use time and the previous replacement date of the equipment constituting the compressor,
The information processing unit calculates a cumulative usage time for each device based on the operation information stored in the storage unit of the operation information as an operating tendency of the compressor, and calculates the cumulative usage time and the lifetime usage The next replacement scheduled date of the device is calculated based on the time and the previous replacement date, and transmitted to a user's computer corresponding to the compressor via a network. The management system of machine equipment as described in any one of 6.

Images