JP2005202774A - Production facility maintenance system, control device for production facility and information processor - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a production facility control device capable of easily performing substituting/restoring operation when a fault is generated. <P>SOLUTION: The production facility control device 10 is provided with a specific identification means 12 for generating identification information for identifying the device 10 itself, a set data storage instruction means 13 for transmiting changed set data and the identification information to a backup server 4 to store these data in the backup server 4 when the set data are changed and a set data restoration means 14 for acquiring the set data corresponding to the identification information generated by the specific identification means 12 from the backup server 4. The backup server 4 merges the identification information transmitted from the set data storage instruction means 13 and the set data and stores the merged data. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a production facility control device, a production facility maintenance system, and an information processing device connected to a network.

  A production line controlled by a conventional production equipment control device (hereinafter referred to as a control device) has a configuration as shown in FIG. The hall computer in the figure corresponds to the control device in the present invention. An IP address in TCP / IP communication is assigned to the hall computer, the terminal device, and the backup server. After obtaining the IP address, a predetermined operation is started, and the terminal device takes in the setting data from the hall computer, and then transfers the setting data to the backup server. In the invention described in Patent Document 1, backup is performed by adding a user account or date to data transferred from the terminal device to the backup server.

  Further, FIG. 1 of Patent Document 2 shows another conventional control device. The server in the figure corresponds to the control device. The file stored in the external storage device provided in this server is measured and held using a counter, and the file is transferred from the server to the backup file server according to the number of updates.

  Further, FIG. 1 of Patent Document 3 shows another conventional control device. In the figure, the backup target server corresponds to the control device. The server to be backed up is devised with regard to the start time of the backup operation, a contrivance regarding the start time zone, a contrivance to change communication parameters depending on the backup data, a contrivance to select a time when the communication path is less busy, Do some ingenuity.

  Further, FIG. 1 of Patent Document 4 shows another conventional control device. In the figure, the system control device corresponds to the control device. Here, a method of converting setting data from binary to text format and transferring it to a backup device is disclosed.

  Further, FIG. 1 of Patent Document 5 shows another conventional control device. In the figure, the remote device corresponds to the control device. Firmware update by the controller is performed by transferring old and new differential data to reduce the amount of data, leaving the old firmware in the storage area, and returning to the old firmware when a failure occurs when starting the new firmware. It was.

JP 2002-288021 A JP-A-6-250902 JP-A-10-31562 JP 9-325904 A JP 2000-330777 A

  The conventional control device is configured as described above, and is premised on manual backup and restoration operations. At that time, there is only one control device, and the control device and the backup device have a one-to-one relationship. What was supposed to work. In addition, when there are a plurality of control devices, it is implicitly understood that the operator performs the distinction between the control devices. Further, data related to the backup of the control device is transferred via the terminal device by the operator operating the terminal device for the worker.

  As a result, when there are a plurality of control devices, there is a problem that the backup operation and the restoration operation cannot be automated. Further, since the restoration operation is performed manually, there is a problem that the adjusted setting data may be lost if the work procedure is not standardized.

  In addition, there was a control device that devised the trigger for performing the backup operation, but the production facility performs an unnecessarily complicated operation even though it is sufficient if the backup is executed when adjustment work is performed. It was broken. Furthermore, although there has been a control device that performs binary text conversion on backup data and saves it in a text format, there is no effect that saving or reusing data by saving in text format is not possible.

  In addition, it is necessary to restart the control device when updating the firmware, which is troublesome. In addition, the firmware is not updated from the control device side, but from the maintenance center side, and there is a problem that it is not possible to cope with a form in which the maintenance department of the production facility performs the update when it is desired to update.

  In addition, workers who perform maintenance setting work must have knowledge about the network, knowledge about production equipment, and knowledge about application software. It takes time to acquire or educate such knowledge, and there is a difference in human ability. However, there is a problem that maintenance accuracy may not be maintained.

  Further, in recent years, with the development and spread of the Internet, it is becoming common to connect a local network as described above to the Internet and access the internal control device from the Internet side to exchange information. However, there is an increasing trend in setting work that requires knowledge of multiple specialized areas, such as setting IP addresses, setting routers and other Internet connection devices, and setting the Internet for applications. There was a problem of taking time.

  The present invention has been made to solve the above-described problems, and an object of the present invention is to provide a production facility control device that can easily perform replacement and restoration work when a failure occurs.

  The production facility control device according to the present invention generates a unique identification means for generating identification information for identifying the device itself, and when the setting data is changed, transmits the changed setting data together with the identification information to the server device. Setting data saving instruction means for saving and setting data restoration means for acquiring setting data corresponding to the identification information generated by the unique identification means from the server device are provided.

  In the production facility maintenance system according to the present invention, the production facility control device identifies the unique identification means for generating identification information for identifying the device itself, and the changed setting data when the setting data is changed. A setting data storing instruction means for transmitting and storing the information together with the information to the server apparatus; and setting data restoring means for acquiring setting data corresponding to the identification information generated by the unique identifying means from the server apparatus. The identification information transmitted from the means and the setting data are stored in combination.

  According to this invention, the production facility maintenance system transmits the identification data for identifying the device itself to the server device together with the identification information when the identification data is changed and the setting data is changed. A setting data storage instructing unit that stores the setting data, and a setting data restoring unit that acquires setting data corresponding to the identification information generated by the unique identification unit from the server device; Since the server apparatus that stores the combination of the transmitted identification information and the setting data is provided, there is an effect that the setting data can be restored without bothering the operator when the production equipment control apparatus is replaced. .

Embodiment 1 FIG.
FIG. 1 is a block diagram of a production equipment control apparatus (hereinafter referred to as a control apparatus) according to Embodiment 1 of the present invention. Moreover, FIG. 2 is a figure which shows the example of a structure when using several this control apparatus and controlling several production equipment. As shown in FIG. 1, the control device 10 includes a network connection unit 11, a unique identification unit 12, a setting data storage instruction unit 13, a setting data restoration unit 14, and a setting data storage unit 15. The control device 10 is connected to the production facility 3 and the IP network 2.

  As shown in FIG. 2, as a system for controlling the production facility 3 by the control device 10, for example, a system including control devices 10 </ b> A to 10 </ b> C, production facilities 3 </ b> A and 3 </ b> B, and a backup server 4 is shown. The control device 10A is connected to the production facility 3A, and the control device 10B and the control device 10C are connected to the production facility 3B to perform control. The control devices 10A to 10C and the backup server 4 are connected to the IP network 2 and can communicate with each other.

  The network connection unit 11 in FIG. 1 connects the control apparatus 10 to the IP network 2 and enables communication with other devices. The unique identification unit 12 generates identification information for distinguishing from other control devices 10 connected to the IP network 2. The setting data storage instructing means 13 detects that the setting data stored in the setting data storage means 15 has been changed directly or remotely by the operator's operation, and starts an operation described later. The setting data restoring unit 14 restores the setting data when the setting data does not exist in the setting data storage unit 15 or when it is deleted (details will be described later). The setting data storage unit 15 stores setting data which is a data group necessary for the control device 10 to perform a control operation. The backup server 4 in FIG. 2 holds setting data of the control devices 10A to 10C.

Next, each component in FIG. 1 will be specifically described.
(1) Control device 10
The control device 10 controls the production facility 3. The control device 10 includes, for example, a programmable logic controller, NC (Numerical Controller), RC (Robot Controller), servo controller, and motion controller, and an appropriate control device corresponding to the production facility 3 is used.

(2) Network connection means 11
The network connection unit 11 performs data communication using the IP network 2 and is configured by hardware suitable for the hardware used for the IP network 2. For example, when Ethernet (registered trademark) is used as the IP network 2, an Ethernet (registered trademark) IC chip group is generally used as hardware of the network connection means 11. The network connection means 11 generally includes so-called device driver software for operating these Ethernet (registered trademark) IC chips and software called a communication protocol stack for performing IP (Internet Protocol) communication.

  When hardware other than Ethernet (registered trademark) is used for the IP network 2, a hardware chip and device driver software corresponding to the hardware are used. For example, a wireless LAN (Local Area Network), an analog or digital telephone line, a mobile phone line, various DSLs (Digital Subscriber Line), an optical fiber, and the like can be used.

(3) Unique identification means 12
In a factory equipped with the production facility 3, a plurality of control devices 10 are usually used. As shown in FIG. 2, a plurality of control devices 10 may control one production facility 3. The unique identification unit 12 generates identification information for identifying the plurality of control devices 10.

  The unique identification means 12 needs to distinguish not only using the manufacturing number and product type of the control device 10 but also the position and role in the production line having the production equipment group and the control device group. This is because when a failure occurs in the operating control device 10, the failed control device 10 is replaced with a normal control device 10, and the setting data can be restored. For this reason, at least a unique number, symbol and name in the production line are required. Ideally, any number, symbol, or name that is unique all over the world may be used, but there is a disadvantage that the data length becomes long. However, it may be considered that this is not a fatal defect according to the recent communication situation and calculation capability.

The unique identification unit 12 holds the unique number, symbol, and name as described above, and answers the content when there is an inquiry from another component.
Here, a method for generating a unique identification number by the unique identification means 12 will be described.

  (A) For example, an ID issued by a public organization such as a ubiquitous ID center (http://www.uidcenter.org/japanese/japanese.html) is used as a unique identification number. Alternatively, an IPv6 (Internet Protocol version 6) address is used as the unique identification number. In this case, the worker manages which control device installed at which position in the production line has which ID, and when the control device 10 is replaced, the worker uses the ID of the control device 10 before replacement as an identification number. Enter manually. The unique identification unit 12 holds the input ID.

  (B) The manufacturing number, product model, and firmware version number of the control device 10 are used as a part of the unique identification number, symbol, and name. In this case, when a new version of the firmware is installed when the control device 10 is replaced with a succeeding new model, it can be read with a data structure and meaning different from the setting data of the old version, and a restoration operation is performed. There is an effect that can.

  (C) The production facility 3 may include a unique identification unit. At this time, information related to the unique identification of the production facility 3 can be used as a part of the unique identification information of the control device 10. In this case, there is an effect that a unique identification number, a symbol, and a name can be automatically generated without bothering a person.

  (D) The geographical position of the control device 10 is acquired by using a GPS (Global Positioning System) or a wireless LAN position identification function, and is used as a part of the unique identification number, symbol, and name. In this case, there is an effect that the unique identification number, the symbol, and the name can be automatically generated without trouble.

  (E) The operator determines the name of the control device 10 and uses it as a unique identification name. When the control device 10 is replaced, the operator manually inputs the unique identification name of the control device 10 before the replacement into the control device 10 after the replacement.

  (F) When the control device 10 is installed, a unique identification name is automatically generated by a random number, which is held by the unique identification means 12 and registered in the backup server 4. After the control device 10 is replaced, the backup server 4 searches for a unique identifier existing in the network at that time, and the registered unique identifier that does not exist is the unique identifier of the controller 10 before replacement. The name is recognized and supplied to the control device 10 after replacement.

  (G) The connection form with the controlled production facility 3 is used as the unique identification information. The connection form refers to the configuration of an I / O (Input / Output) unit or the like of the control device 10 and the allocation state of I / O lines. In this case, there is an effect that the unique identification number, the symbol, and the name can be automatically generated without trouble.

  (H) An operator attaches a barcode or an identification element such as a wireless ID tag to the vicinity of the installation position of the control device 10 or a so-called base unit (bus) where a controller is installed, or describes a serial number The control device 10 is provided with means for reading the identification information. The control device 10 reads the identification information when it is installed or when requested, and generates and holds a unique identification number, symbol, and name based on the identification information.

  When a bar code is pasted on the base unit or when a numerical value is described, the image can be read by providing the control device 10 with an image sensor and a CCD camera. On the other hand, when the wireless ID tag is provided, reading is performed by providing a dedicated reading circuit in the control device 10. Alternatively, when a predetermined inquiry signal is received on the base unit side, a means for returning unique identification information (for example, the serial number of the base unit and the position on the base unit) is provided, and immediately after the control device 10 is installed, Alternatively, the unique identification information may be read out by issuing this predetermined inquiry signal immediately after the power is turned on. In this case, there is an effect that the unique identification number, the symbol, and the name can be automatically generated without trouble.

(4) Setting data storage instruction means 13
The setting data storage instruction unit 13 is a unit that is activated and executed when the setting data of the control device 10 is changed. The setting data saving instructing unit 13 transfers the changed setting data and the information for unique identification obtained by the unique identifying unit 12 to the backup server 4 via the IP network 2 and stores them.

  The operation of the setting data storage instructing means 13 is started when the operator manually changes the setting data, or at regular intervals such as once a day or at the start of work. Some types of control device 10 have a function of automatically changing setting data. That is, it is a function for improving the control performance by changing the setting data in accordance with the characteristics of the controlled object. In the control device 10 having such a function, the setting data saving instruction unit 13 starts the operation when the automatic setting data changing operation is completed.

(5) Setting data restoring means 14
The setting data restoration unit 14 holds data at the time of shipment of the control device 10 from the factory. When the control device 10 is turned on, the data at the time of factory shipment is compared with the setting data stored in the setting data storage means 15 to determine whether or not the setting data remains at the time of factory shipment. If it is determined that the factory-shipped state is maintained, the unique identification information generated by the unique identification unit 12 is acquired, and the unique identification information and the inquiry request are transmitted to the backup server 4. Subsequently, data transferred as a response to the inquiry request from the backup server 4 is received and stored in the setting data storage means 15. The inquiry request may include date information and version number information. In this case, the backup server 4 searches the stored data using date information and the version number as a search key, acquires the corresponding data, and sends it back to the control device 10. The setting data restoring means 14 may be operated not only when the control device 10 is turned on but also when the setting data is deleted, according to the operation of the operator.

(6) Setting data storage means 15
The setting data storage unit 15 stores setting data that is a data group related to the control operation of the control device 10. The control device 10 controls the operation of the production facility 3 based on the setting data. For example, when the control device 10 is a servo amplifier and the motor to be controlled is controlled by PID (Proportional Integral Derivative), a value called gain for each of P, I, and D is set data.

  Moreover, in the control apparatus for driving the movable part of the production facility 3, the stop position coordinate of the movable part may be set as setting data in advance. The stop position coordinates are called a teaching position or simply a position. In addition to these, whether or not optional devices or parts are externally attached, various gains, various time constants, various function selections, various limiting values such as maximum rotation speed and maximum output, various offset values, various filter constants, Alternatively, unique setting values are included in this setting data.

  Furthermore, if the IP address value for connecting the control device 10 to the Internet, the setting value of an Internet connection device such as a router, the Internet compatible setting value of the application, etc. are set as setting data, the control device 10 via the Internet is set. Easy access to.

The data format of the setting data can be expressed using XML (extensible Markup Language), which is becoming mainstream in recent years. For example, when the control device 10 is a PID control device, values called gains of P, I, and D are set data.
<Setting data>
<P gain> 10 </ P gain>
<I gain> 20 </ I gain>
<D gain> 20 </ D gain>
</ Setting data>
It can be expressed using the XML data format.

Such setting data is exchanged between the control device 10 and the backup server 4. When the setting data is expressed in XML as described above, the date and the uniqueness are stored when the setting data is stored in the backup server 4. The identification information, the setting data, the operator's comment, and the control performance index based on the setting data may be stored together, and the notation in XML at that time is, for example, as follows.
<Request>
<Request type> save </ request type>
<Date> December 24, 2003 </ Date>
<Unique identification information> 54848566 </ unique identification information>
<Worker comment> Vibration suppression, completion </ Worker comment>
<Performance index> Overshoot amount 0.1 </ Performance index>
<Setting data>
<P gain> 10 </ P gain>
<I gain> 20 </ I gain>
<D gain> 20 </ D gain>
</ Setting data>
</ Request>

  By configuring the backup server 4 using, for example, a native XML database (for example, Xindice developed as one of the projects of The Apache Software Foundation), the above-described storage request by XML is retained in the database. Keep it. At this time, the saving request and restoring request sent from the control device 10 are shown in Xpath (shown in http://www.w3.org/) and XUpdate (http://xmldb.org/). ), XQuery (shown in http://www.w3.org/) and the like. When the control device 10 creates a character string based on these rules and transmits it to the backup server 4, the backup server 4 interprets the character string and performs a predetermined operation. If the transmitted request type is a save request, the setting data and the like are saved in the backup server 4, and if it is a restore request, the unique identification information is used as a search key and the XML stored by the user is saved. The data is searched and sent back to the control device 10.

  FIG. 3 is a flowchart showing the operation of the production facility maintenance system according to Embodiment 1 of the present invention. The operations of the control device 10 and the maintenance system will be described with reference to this figure.

First, the operation of the backup server 4 shown in FIG. 3 will be described.
When the power is turned on, the backup server 4 starts a predetermined operation and waits for requests from a plurality of control devices 10 connected via the IP network 2 (step ST101). When a request from the control device 10 is received, the request content is analyzed (step ST102). If the requested content is a request to save the setting data of the control device 10, the unique identification information and the setting data transmitted from the control device 10 are saved as a set in the storage means 41 (step ST103). As a storage method, for example, a method of overwriting and storing only the latest data, a method of storing the latest data and the previous data, or a plurality of date information when the backup server 4 obtains setting data. There is a way to save data.

  On the other hand, when the request content from the control device 10 requests to restore the setting data, the unique identification acquired from the control device 10 from the storage means 41 storing the combination of the unique identification information and the setting data. A set including information is taken out and setting data is transmitted to the control device 10 (step ST104). When a plurality of sets are obtained, the one corresponding to the purpose is selected and transmitted. After performing the above operation, it waits for a request from the control device 10 again (step ST101).

  After receiving the request in step ST101, the request content analysis (step ST102), the setting data storage (step ST103) and the setting data transmission (step ST104) are executed as a separate thread, a separate process, or a separate task. The thread (or process or task) may return immediately to step ST101 and wait for the next request. In this case, inquiry requests transmitted from a plurality of control devices 10 can be processed in parallel, and there is an effect that the time for each control device to be in a process waiting state can be reduced.

Next, the operation of the control device 10 in FIG. 3 will be described.
When the power is turned on, the control device 10 activates two threads or processes or tasks (hereinafter, only threads will be described. The effect is the same for processes and tasks). Of the two threads to be activated, the first thread is a thread that is in charge of the setting data storage instructing means 13 and always operates while the control device 10 is energized. That is, the setting data storage instructing means 13 constantly monitors whether the setting data has been changed (step ST201), and when the change is detected, acquires the unique identification information from the unique identification means 12 (step ST202), and the backup server 4 issues a transfer request (step ST203). Subsequently, the unique identification information and the setting data are transmitted to the backup server 4 (step ST204). After the transmission, it is monitored again whether the setting data is changed (step ST201).

  On the other hand, the setting data restoration means 14 is in charge of the second thread, and checks the state of the setting data when the control device 10 is powered on (step ST301). When the setting data is in the factory-shipped state, the unique identification information is acquired from the unique identification means 12 (step ST302), and a setting data restoration request is transmitted to the backup server 4 together with the unique identification information (step ST303). Subsequently, the setting data is received from the backup server 4 (step ST304) and stored.

  There is also a third thread that is manually activated by the operator. This thread is handled by the setting data restoring means 14 and is used when setting data is manually retrieved. For example, it is used when it is necessary to return to the previous setting state for some reason. When activated by the operator, the setting data restoration unit 14 acquires unique identification information from the unique identification unit 12 (step ST401), and sends an acquisition request for data immediately before the setting data to the backup server 4 together with the unique identification information. Transmit (step ST402). Subsequently, the setting data is received from the backup server 4 (step ST403) and stored.

  In step ST104, a plurality of corresponding setting data may be acquired. In this case, when the setting data is saved, the setting data and other information are saved in combination and transmitted to the control device 10. The control device 10 selects one appropriate data from a plurality of corresponding setting data candidates.

  Here, the information stored in combination with the setting data will be described. For example, the setting data and the storage date may be combined. Moreover, you may combine an operator's comment, for example, the memo about the content of adjustment work, and setting data. Further, the setting data and the control performance based on the setting data may be combined. As the control performance, for example, a settling time of a predetermined control operation, an overshoot amount of a predetermined step response, a phase margin, a gain margin, or the like may be used.

  On the other hand, the control apparatus 10 selects one appropriate data from a plurality of candidates. When the storage date is stored together with the setting data, all data having the corresponding storage date is transmitted to the control device 10. The control device 10 selects an appropriate one from the acquired data. Further, the backup server 4 may transmit only the latest data. In step ST303, that is, when it is detected that the setting data of the control device 10 is in the factory shipment state, it is appropriate to transmit only the latest data in this way.

  Also, in step ST401, that is, when the setting data is changed and adjusted, but it is better to use the previous setting data, the setting data saved immediately before the latest setting data is taken out. It is appropriate to transmit to the control device 10. Furthermore, when the backup server 4 stores a combination of the operator's comment character string after adjustment work of the control device 10 and the setting data, the control device 10 selects a plurality of candidates based on the comment character string. Select one from Similarly, when the control performance and the setting data are stored in combination, the control device 10 selects one similarly.

Note that the above combinations may be further combined and stored. For example, the operator's comment, control performance, and setting data may be stored in combination.
As described above, the backup server 4 has an effect of selecting data suitable for the purpose from a plurality of setting data by storing various information in combination.

  In the first embodiment, the case where a personal computer is used as the backup server 4 has been described. In recent years, a system form called P2P (Peer to Peer) is being used. According to P2P, for example, the file storage areas of the control devices 10 that can communicate with each other via the IP network 2 can be shared with each other via the network connection means 11 and can appear to be virtually large file areas. Also in the first embodiment, the function of the backup server 4 can be realized by using such P2P. In this case, since the maintenance system of the production facility 3 can be configured with only the plurality of control devices 10 without using a personal computer, the cost can be reduced and the operation can be simplified.

  As described above, according to the first embodiment, the setting data storing instruction unit 13 stores the changed setting data in the backup server 4 when the setting data is changed, and the setting data restoring unit 14 is used for the control device. Since the setting data is acquired from the backup server 4 when it is detected that the setting data is the data at the time of shipment from the factory at the time of starting 10, before the replacement is automatically performed when the operator replaces the control device 10. Can restore the setting data. Therefore, as compared with the conventional case where the restoration operation is manually performed on the plurality of control devices 10, there is an effect that the control device 10 can appropriately manage and hold the setting data without being dissipated.

  Further, when the control device 10 has a function of automatically changing the setting data to improve the control performance, manual work by the operator is unnecessary, but the automatic change process takes time. On the other hand, in the control device 10 according to the first embodiment, the setting data storage instructing means 13 stores the setting data in the backup server 4 when the automatic setting data changing operation is completed, and when the control device 10 is activated. Since the setting data restoring unit 14 restores, an effect that the time required for the change can be reduced is obtained.

  In addition, since the setting data includes setting values for network connection, setting values for production equipment, and setting values for application software, even if the person does not have specialized knowledge, it is only necessary to replace the control device 10. The setting data before replacement can be restored, and the effect of maintaining maintenance accuracy can be obtained. Further, since the setting data includes an IP address value for the control device 10 to connect to the Internet, a setting value of an Internet connection device such as a router, an Internet-compatible setting value of an application, etc. However, it is possible to obtain an effect of enabling access to the control device 10 via the Internet.

Embodiment 2. FIG.
FIG. 4 is a block diagram of a control device according to Embodiment 2 of the present invention. In the figure, components common to those in FIG. 1 are denoted by the same reference numerals and description thereof is omitted. As shown in the figure, in the second embodiment, the control device 10 shown in the first embodiment further includes a display unit 16 and an input unit 17. The display means 16 displays restoreable setting data candidates stored in the backup server 4. The input unit 17 is a unit for the operator to select appropriate data from the candidates displayed on the display unit 16.

  As shown in the first embodiment, the backup server 4 stores the setting data and other information in combination when saving the setting data. The control device 10 displays the setting data candidates held by the backup server 4 on the display means 16 so that the operator selects one appropriate data from the input means 17.

  The display means 16 is input by, for example, a candidate number of the setting data that can be restored, the date when the setting data is stored, the performance of the control operation based on the setting data, for example, the overshoot amount of a predetermined step response, and the stored worker Display comments etc. The operator inputs the candidate number displayed on the display unit 16 from the input unit 17.

  When an appropriate candidate is selected by the operator, the input unit 17 transmits the selected candidate number to the backup server 4 via the network connection unit 11. The backup server 4 acquires setting data corresponding to the acquired candidate number and sends it back to the control device 10. The control device 10 stores the received setting data.

  FIG. 5 is a configuration diagram showing a production facility maintenance system according to the second embodiment. In the figure, components common to those in FIG. 2 are denoted by the same reference numerals and description thereof is omitted. As shown in the figure, a unit having the above-described display means and input means is provided independently and connected to the IP network 2. The display means 16B and the input means 17B can communicate with the control devices 10A to 10C and the backup server 4 via the IP network 2. The input means 17B notifies the backup server 4 via the IP network 2 when the candidate number is selected by the operator. The backup server 4 acquires setting data corresponding to the candidate number and transmits it to the corresponding control device 10A, 10B, or 10C.

  The display means 16A and the input means 17A are connected to the control device 10A via a serial communication line 21 called RS232C. In this case, the setting data transmitted from the backup server 4 in response to a request from the input unit 17A is supplied to the unit including the display unit 16A and the input unit 17A via the IP network 2. Subsequently, the setting data is transmitted to the control device 10A via the serial communication line 18. In this case, the control device 10A may not be connected to the IP network 2.

  Note that a notebook personal computer may be used as a device including the display means 16A, the input means 17A, and a serial communication line. Further, the backup server 4 may be provided with a display unit and an input unit, and desired setting data may be transmitted to the control devices 10A to 10C in accordance with the operator's operation. Further, when the setting data acquired from the backup server 4 is stored in the control device 10, the operation of the control device based on the setting data may be executed by the operator operating the input unit 17. At this time, the operator may use the input unit 17 to input a comment to the setting data.

  As described above, according to the second embodiment, the display unit 16 displays the setting data candidates stored in the backup server 4, and the operator uses the input unit 17 to select appropriate setting data. Since it did in this way, the effect that the setting data according to the objective can be taken in into the control apparatus 10 is acquired.

Embodiment 3 FIG.
FIG. 6 is a block diagram of a control apparatus according to Embodiment 3 of the present invention. In the figure, components common to those in FIG. As shown in the figure, in the third embodiment, a setup personal computer 19 having the function of the control device 10 shown in the second embodiment controls the control device 10.

  The setup personal computer 19 includes network connection means 11, unique identification means 12, setting data storage instruction means 13, setting data restoration means 14, display means 16, and input means 17, and these operations are the same as those in the first and second embodiments. It is the same as the operation shown. The display means 16 and the input means 17 may be a display and a keyboard included in the setup personal computer 19, respectively.

  The setup personal computer 19 further includes setup software 20. The setup software 20 is adjustment software dedicated to the control device 10 connected to the setup personal computer 19 and sets operation parameters of the control device 10. The control device 10 and the setup personal computer 19 are connected by a serial communication line 21, and setting data is transmitted / received via the serial communication line 21 when the control device 10 is adjusted.

  As the unique identification means 12, here, an example is shown in which unique identification information is generated from the barcode 22 pasted near the attachment position of the control device 10. When there are a plurality of control devices 10, the bar code 22 is pasted in the vicinity of the attachment position of the control device 10, thereby identifying the plurality of control devices 10. The setup personal computer 19 includes a barcode reader 23 that reads the barcode 22. For the barcode reader 23, for example, a commercially available product that can be connected in parallel with a keyboard of a personal computer is used.

  The setting data storage instruction unit 13 is activated when the setting data of the control device 10 is changed as described in the first embodiment. On the other hand, the setting data restoring means 14 is activated when it is detected that the setting data remains the factory shipment data when the control device 10 is powered on. The operator reads the value of the barcode 22 by using the barcode reader 23 when the setup personal computer 19 is turned on.

As described above, the example in which the setup personal computer 19 is configured by the personal computer provided with the setup software 20 has been described. Here, the setup personal computer 19 without the setup software 20 is also described.
The setup personal computer 19 without the setup software 20 cannot adjust the setting data of the control device 10, but reads the setting data from the control device 10 and sends a save request to the backup server 4 together with the unique identification information. Or the setting data transmitted from the backup server 4 in response to a restoration request can be written in the control device 10. Such a setup personal computer 19 may not be a personal computer, but may be a so-called handy type barcode or ID tag reader, but here it will be called a setup personal computer.

The operation of the setup personal computer 19 having such a configuration will be described.
It is assumed that the setting data is rewritten in the control device 10. This is a case where an operator performs setup work using another personal computer and the work is completed. Thereafter, the operator reads the barcode 22 using the barcode reader 23 of the setup personal computer 19, and the unique identification means 12 acquires the unique identification information. Subsequently, the setting data saving instruction means 13 reads the setting data from the control device 10 via the serial line 21 and sends a saving request to the backup server 4 together with the unique identification information acquired by the unique identification means 12.

  On the other hand, when the setting data restoration unit 14 sends a restoration request to the backup server 4 together with the unique identification information acquired by the unique identification unit 12, the backup server 4 reads the corresponding setting data based on the obtained unique identification information. Then, transfer to the setup personal computer 19. The setting data restoring means 14 sends this setting data to the control device 10 via the serial line 21 and writes it.

In the embodiment described above, an example in which the setup personal computer 19 and the control device 10 are connected via the serial line 21 has been described. However, the control device 10 and the setup personal computer 19 are directly connected to the network 2. The same effect can be obtained. Therefore, the operation in this case will be described.
When the setting data storage instruction unit 13 of the setup personal computer 19 sends a storage request together with the unique identification information acquired by the unique identification unit 12 to the backup server 4, the backup server 4 sends a backup request from the control device 10 corresponding to the unique identification information. Read and save the setting data. Alternatively, the setting data storage instruction unit 13 issues an instruction to send the setting data to the backup server 4 to the control device 10 corresponding to the unique identification information, and the control device 10 that has received the instruction sends the setting data to the backup server 4. It may be sent out and stored.

  On the other hand, when the setting data restoration unit 14 sends a restoration request together with the unique identification information to the backup server 4, the backup server 4 reads the setting data corresponding to the unique identification information and sends the setting data to the control device 10. Alternatively, the setting data restoration unit 14 issues an instruction to read the setting data from the backup server 4 to the control device 10 corresponding to the unique identification information, and the control device 10 that has received the instruction sends the setting data to the backup server 4. A restoration request may be sent.

  As described above, according to the third embodiment, since the setup personal computer 19 is used to save and restore the setting data of the control device 10, the control device without the network connection means 11 is also implemented. As in the first to third embodiments, the setting data can be saved and restored using the backup server 4.

Embodiment 4 FIG.
FIG. 7 is a block diagram of a control device according to Embodiment 4 of the present invention. In the figure, components common to those in FIG. 1 are denoted by the same reference numerals and description thereof is omitted. As in the first embodiment, the control device 10 is connected to the IP network 2 by the network connection means 11. In addition, the control device 10 includes firmware 24, constant data 25, and data update means 26.

  The firmware 24 is software that controls the operation of the control device 10, and the constant data 25 is data that is used as a reference when the control device 10 operates. The data update unit 26 updates the firmware 24 and the constant data 25 to the latest state. That is, the data updating unit 26 acquires the latest data from a later-described latest data providing server via the IP network 2 and updates the firmware 24 and the constant data 25 to the latest version.

  FIG. 8 is a block diagram showing a production facility maintenance system according to Embodiment 4 of the present invention. In the figure, components common to those in FIG. The production facility maintenance system according to the fourth embodiment includes the latest data providing servers 6A and 6B. The latest data providing server 6A can communicate with the IP network 2 and the latest data providing server 6B via the Internet network 5. The latest data providing server 6B is connected to the IP network 2.

  The latest data providing server 6A is provided by the manufacturer of the control devices 10A to 10C to provide the latest firmware 24 and constant data 25 to the control devices 10A to 10C. The latest data providing server 6A holds firmware 24 and constant data 25 relating to operation control of the production facilities 3A to 3C in association with the identification information of the control devices 10A to 10C. As described above, the data update unit 26 in FIG. 6 takes out the latest data from the latest data providing server 6A. On the other hand, the latest data providing server 6B is provided on the IP network 2, that is, the LAN, and this is used when the data update means 26 cannot communicate via the Internet network 5. The latest data providing server 6B acquires and holds the latest data from the latest data providing server 6A. Further, the latest version may be imported from the latest data providing server 6A to the latest data providing server 6B via a medium such as a CD-ROM. It is assumed that the data updating unit 26 performs the same operation on the latest data providing servers 6A and 6B.

FIG. 9 is a flowchart showing the operation of the production facility maintenance system according to Embodiment 4 of the present invention. The operation of this maintenance system will be described with reference to this figure.
The control device 10 updates the firmware 24 and the constant data 25 to the latest version based on the operator's operation, at a predetermined cycle, or when the power is turned on. For example, when there is an update instruction from the worker, the data update unit 26 instructs the unique identification unit 12 to acquire unique identification information regarding the control device 10. The unique identification means 12 acquires unique identification information based on the instruction (step ST501). Here, the product type and serial number of the control device 10 are used as the unique identification information. The unique identification unit 12 supplies the acquired unique identification information to the data update unit 26.

  Subsequently, the data updating unit 26 acquires information on the current data held by the control device 10, for example, version information of the firmware 24 and the constant data 25 (step ST502). The control device 10 divides these data into a plurality of parts, and assigns a version number to each part. As for the dividing method for the firmware 24, it is effective that the operating system of the control device 10 divides the firmware 24 into units for loading the memory 24, for example, for each dynamic load library.

  Subsequently, the data updating unit 26 creates an update request data packet including the acquired unique identification information and information regarding the current data, and transmits the update request data packet to the latest data providing server 6A via the Internet 5 by the network connection unit 11. (Step ST503). Latest data providing server 6A is waiting to receive an update request from control device 10 (step ST504). When receiving the update request, the latest data providing server 6 </ b> A determines whether or not the latest version data corresponding to the received information is stored in the storage unit (data storage unit) 41. Here, the storage means 41 of the latest data providing server 6A stores unique identification information, version numbers, and combinations of corresponding data. That is, firmware and constant data corresponding to each version number are stored for each product model.

  Based on the unique identification information and version information acquired from the control device 10, the latest data providing server 6 </ b> A can store data having a version number newer than the version number transmitted from the control device 10 in the storage unit 41. Applicable latest version data is acquired and returned to the control device 10 from a data transmission means (not shown) (step ST505). If the latest version data is not stored, the process returns to the request reception waiting state (step ST504). The control device 10 receives the latest version data from the latest data providing server 6A (step ST506), and overwrites the corresponding firmware 24 and constant data 25 (step ST507). The above operation may be similarly performed on the latest data providing server 6B.

  In the fourth embodiment, the data updating unit 26 updates the firmware 24 in units of DLL (Dynamic Link Library). Therefore, the updated firmware 24 can be executed without restarting the control device 10.

  As described above, according to the fourth embodiment, the firmware 24 and the constant data 25 are updated by the data updating unit 26 based on the operation of the worker, at a predetermined cycle, or when the power is turned on. Is updated to the latest version, the control device 10 can obtain the effect of keeping these data up-to-date.

It is a block diagram of the control apparatus for production facilities by Embodiment 1 of this invention. It is a figure which shows the structural example when using a plurality of control apparatuses by the same Embodiment 1 and controlling a plurality of production facilities. It is a flowchart which shows operation | movement of the maintenance system of the production facility which concerns on the same Embodiment 1. FIG. It is a block diagram of the control apparatus for production facilities by Embodiment 2 of this invention. It is a block diagram which shows the maintenance system of the production facility which concerns on the same Embodiment 2. It is a block diagram of the control apparatus by Embodiment 3 of this invention. It is a block diagram of the control apparatus by Embodiment 4 of this invention. It is a block diagram which shows the maintenance system of the production facility by Embodiment 4 of this invention. It is a flowchart which shows operation | movement of the maintenance system of the production facility by the same Embodiment 4.

Explanation of symbols

  2 IP network, 3, 3A-3C production equipment, 4 backup server, 5 Internet network, 6A, 6B latest data providing server, 10, 10A-10C control device, 11 network connection means, 12 unique identification means, 13 setting data storage Instructing means, 14 Setting data restoring means, 15 Setting data storage means, 16, 16A, 16B Display means, 17, 17A, 17B Input means, 18, 21 Serial communication line, 19 PC for setup, 20 Setup software, 22 Bar code , 23 Bar code reader, 24 firmware, 25 constant data, 26 data update means, 41 storage means (data storage means).

Claims (7)

One or a plurality of production facility control devices that control the operation of the production facility based on setting data that is a data group related to the control operation, and a server device that can communicate with the production facility control device via a communication network In production equipment maintenance system with
The production equipment control device comprises:
Unique identification means for generating identification information for identifying the device itself;
When the setting data is changed, setting data storage instruction means for transmitting the setting data after the change to the server device together with the identification information and storing it,
Setting data restoration means for obtaining setting data corresponding to the identification information generated by the unique identification means from the server device;
The server device is
A production facility maintenance system characterized by storing the identification information and setting data transmitted from the setting data storage instruction means in combination.   The setting data restoring means determines whether or not the setting data remains at the time of factory shipment at the time of startup, and corresponds to the identification information generated by the unique identification means when the data at the factory shipment remains as it is. 2. The production facility maintenance system according to claim 1, wherein the setting data is acquired from a server device.   The server device stores the identification information and the setting data in combination with at least one of the date information when the setting data is saved, the performance index of the control operation based on the setting data, and the operator's comment when the setting data is saved. The production facility maintenance system according to claim 1 or 2, characterized in that In the production facility control device capable of controlling the operation of the production facility based on the setting data which is a data group related to the control operation, and capable of communicating via a communication network with a server device that holds information regarding the setting data,
Unique identification means for generating identification information for identifying the device itself;
When the setting data is changed, setting data storage instruction means for transmitting the setting data after the change to the server device together with the identification information and storing it,
A production facility control apparatus comprising: setting data restoring means for acquiring setting data corresponding to the identification information generated by the unique identification means from the server apparatus. Based on the firmware that controls the operation and the constant data that is referenced and used during operation,
In a production facility maintenance system comprising one or more production facility control devices that control the operation of a production facility, and a server device that can communicate with the production facility control device via a communication network,
The server device is
Firmware and constant data relating to operation control of the production facility in association with identification information of the production facility control device, and data storage means for holding version information thereof,
When version information and identification information are acquired from the production equipment control device, it is determined whether firmware and constant data of a version newer than the acquired version are held, and if so, the corresponding firmware And data transmission means for transmitting constant data to the production equipment control device corresponding to the identification information,
The production equipment control device comprises:
Unique identification means for generating identification information for identifying the device itself;
The firmware and constant data version information held by itself and the identification information generated by the unique identification means are transmitted to the server device, and the firmware and constant data acquired from the server device A production facility maintenance system comprising a data update means for updating firmware and constant data. In the production facility control device capable of controlling the operation of the production facility and communicating with the server device holding the firmware and constant data related to the operation control of the production facility via a communication network,
Unique identification means for generating identification information for identifying the device itself;
Firmware and constant data version information on operation control of the production facility and identification information generated by the unique identification means are transmitted to the server device, and firmware and constant data acquired from the server device A production facility control device comprising: data updating means for updating existing firmware and constant data. In a production equipment control device that controls the operation of a production facility based on setting data that is a data group related to a control operation, and an information processing device that is in communication connection with a server device that holds information related to the setting data.
Unique identification means for generating identification information for identifying a control device for production equipment connected to the device;
When the setting data is changed, setting data storage instruction means for transmitting the setting data after the change to the server device together with the identification information and storing it,
Setting data restoration means for obtaining setting data corresponding to the identification information generated by the unique identification means from the server device;
An information processing apparatus comprising: setup means for supplying the setting data acquired by the setting data restoring means to the production equipment control device.

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