WO2012049771A1 - 自動遠隔監視診断システム - Google Patents
自動遠隔監視診断システム Download PDFInfo
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- WO2012049771A1 WO2012049771A1 PCT/JP2010/068179 JP2010068179W WO2012049771A1 WO 2012049771 A1 WO2012049771 A1 WO 2012049771A1 JP 2010068179 W JP2010068179 W JP 2010068179W WO 2012049771 A1 WO2012049771 A1 WO 2012049771A1
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- G05B23/02—Electric testing or monitoring
- G05B23/0205—Electric testing or monitoring by means of a monitoring system capable of detecting and responding to faults
- G05B23/0259—Electric testing or monitoring by means of a monitoring system capable of detecting and responding to faults characterized by the response to fault detection
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Definitions
- This invention relates to an automatic remote monitoring diagnosis system.
- an electronic control device for plant equipment or a device such as a plant may be affected by the installation environment during its operation, and may fail or malfunction. Therefore, it becomes necessary to investigate the installation environment of the electronic control device or the like.
- This investigation of the installation environment has conventionally been conducted before delivery of equipment including electronic control devices, etc., when equipment is installed, during periodic inspections of equipment, or when there is some sudden inconvenience in electronic control devices, etc. It was common to take place at a certain point in time.
- the measurement period of various data in this survey is a short period of several weeks at most. That is, the measurement of data is a one-time operation, and monitoring and diagnosis of abnormality that has continued for a long period of time is not performed.
- the contractor and other workers who undertake the measurement must first use a measuring instrument such as a thermometer, hygrometer, accelerometer, gas concentration meter, voltmeter, ammeter or electromagnetic wave meter. Set on site. Next, after measuring for a certain period of time, the worker goes back to the site and brings back the measurement data. Then, it is common to go through a series of processes in which the measurement data brought back is analyzed, compiled into a report, and submitted to the client. Therefore, the investigation of the installation environment has a problem that much labor and cost are required for data measurement, collection, analysis and reporting.
- a measuring instrument such as a thermometer, hygrometer, accelerometer, gas concentration meter, voltmeter, ammeter or electromagnetic wave meter.
- Patent Document 1 measures only so-called environmental data of temperature, humidity, and corrosive gas concentration among various measurement data in the above-described installation environment survey.
- the measured environmental data is input to the diagnostic client.
- the diagnostic client sends environmental data to the diagnostic server.
- This environmental data is transmitted via the Internet.
- the diagnostic server estimates the lifetime and the degree of deterioration of the equipment based on the environmental data while referring to the information stored in the diagnostic database, and presents the estimation result and the coping method to the diagnostic client.
- Patent Document 2 shows that an environmental sensor for measuring the installation environment of various devices in the control panel and a physical sensor for measuring physical quantities of various devices in the control panel are provided in the control panel. It is what. And the measurement data by these sensors are transmitted to the monitoring apparatus (computer system) outside a control panel by wireless communication.
- This monitoring device is equipped with an algorithm for monitoring the soundness of the environment of the control panel based on the correlation between changes in measurement data and a knowledge database relating to environmental standards stored in advance. Then, when an abnormality occurs, the location / cause of the abnormality is estimated, and the content of countermeasure support is output on the screen of the monitoring device.
- Patent Document 1 only environmental data that has a direct influence on the operation of the electronic control device or the like is measured, and a voltage or current that directly affects the operation of the electronic control device or the like. Physical data such as electromagnetic waves and static electricity are not measured. Therefore, it is possible to determine the state of the environmental atmosphere in which the device is placed, and to estimate whether or not an abnormality may occur in the electronic control unit or the like from the state of the environmental atmosphere. However, since it is not possible to directly determine that an abnormality has occurred in the electronic control device or the like, and the cause of the abnormality that has occurred in the electronic control device or the like cannot be determined, an appropriate coping method for solving the problem There is a problem that cannot be presented.
- the measurement data from a sensor group are transmitted to a monitoring apparatus by radio
- a communicable distance, the number of connections, and the like are limited.
- the scale of a plant or factory to be monitored is large or when a plurality of remote locations are to be monitored, it becomes impossible to monitor all the monitoring targets with only one monitoring device. Therefore, when multiple monitoring devices are used according to the scale of the monitoring target, etc., the problem that the data cannot be collectively managed and the measurement data other than the monitoring device that stores the measurement data There is a problem that it cannot be referred from the place of.
- Patent Document 1 what is described in Patent Document 1 is based on the premise that diagnosis result data in a plurality of monitoring targets is shared among a plurality of diagnosis requesters. For this reason, the diagnostic client and the diagnostic server are connected via the Internet, and the measurement data is always transmitted via the Internet. Therefore, when the measurement requester does not want to disclose the measurement data to others or when strong security is required, there is a problem that the system cannot be closed within the company.
- the present invention has been made to solve such a problem, and continuously and automatically collects environmental data and physical data related to an electronic control device, etc., and analyzes the collected data in real time. Diagnose the presence / absence of abnormalities in control devices, etc., and automatically present the results of this analysis / diagnosis and treatment methods if necessary, and flexibly according to the status / status of the monitoring target / diagnostic client An automatic remote monitoring diagnostic system that can be constructed in a simple manner is obtained.
- an environmental sensor that measures environmental data related to an installation environment of an electronic control device or equipment at a predetermined measurement cycle, and transmits the measurement data by wireless communication, and the electronic control device or The physical data related to the device is measured at a predetermined measurement cycle, and the physical sensor that transmits the measurement data by wireless communication and the measurement data transmitted by wireless communication from the environmental sensor and the physical sensor are collected, and the collected measurement
- a wireless server for transmitting data at a predetermined time interval, and the wireless server and the first communication network are communicably connected, and the measurement data transmitted from the wireless server is collected via the first communication network.
- a diagnostic client that transmits the collected measurement data at a predetermined time interval;
- the measurement data transmitted from the diagnostic client is received via the second communication network, and is connected to the electronic control device based on the received measurement data.
- a diagnosis server that performs device diagnosis, a data storage device that stores the measurement data received by the diagnosis server, and a knowledge database that stores information necessary when the diagnosis server performs the diagnosis.
- the diagnostic server transmits the result of the diagnosis to the diagnostic client via the second communication network, and if there is a problem with the electronic control unit or device as a result of the diagnosis, to this problem And determine the handling method of the diagnostic client via the second communication network.
- the automatic remote monitoring and diagnosis system In the automatic remote monitoring and diagnosis system according to the present invention, environmental data and physical data related to the electronic control device, etc. are continuously and automatically measured and collected, and the collected data is analyzed in real time to check whether there is an abnormality in the electronic control device, etc. It is possible to automatically present the results of this analysis / diagnostic and the treatment method if necessary, and to flexibly construct it according to the status / state of the monitoring target / diagnostic client. The effect that it is.
- FIG. FIG. 1 relates to Embodiment 1 of the present invention.
- FIG. 1 shows the overall configuration of an automatic remote monitoring diagnosis system.
- 1a, 1b, and 1c are A company, B company, and C company, respectively, who are diagnosis requesters of the state of the electronic control device or the like.
- diagnosis requesters are three, it may be any number.
- These A company 1a, B company 1b, and C company 1c are equipped with an electronic control unit (not shown) that is a monitoring / diagnosis target of the automatic remote monitoring diagnostic system according to the present invention.
- an environmental sensor 2 and a physical sensor 3 are installed in the casing of the electronic control device or the like or around the electronic control device or the like of these diagnosis requesters.
- the environmental sensor 2 is a sensor group composed of a plurality of sensors that measure environmental data such as temperature, humidity, vibration (acceleration), and corrosive gas concentration.
- the environment sensor 2 including such a sensor group has a function of measuring each measurement element at a predetermined measurement cycle determined for each measurement element and transmitting the measured data by wireless communication.
- the measurement period of these elements may be set to about 1 minute, 10 minutes, or 30 minutes, for example.
- the vibration (acceleration) is considered to change instantaneously. Therefore, it is necessary to measure at a short time interval, and it is desirable to set the measurement cycle to about 10 milliseconds from the experience of the present inventor.
- a semiconductor integrated type can be used as a sensor unit for measuring these elements.
- This semiconductor integrated sensor part is widely used and is easily available.
- a wireless communication device which will be described in detail later, an MPU (Micro Proceding Unit) and a memory, in this sensor unit, a small sensor that can be installed inside an electronic control device or the like can be easily configured. Can do.
- a gas sensor that outputs the measurement result as an electrical signal such as voltage or current to the sensor unit, and measure the temperature and humidity described above for the sensor that can capture this electrical signal.
- an electrical signal such as voltage or current
- the sensor By configuring in the same manner as the sensor, a small one can be easily realized.
- a gas sensor which outputs a measurement result as electric signals such as a voltage and an electric current
- there exist a thing of systems such as a semiconductor type, a solid electrolyte type, and an electrochemical system, for example, you may use the thing of any system.
- the physical sensor 3 is a sensor group including a plurality of sensors that measure physical data such as voltage, current, electromagnetic waves, and static electricity. As with the environmental sensor 2, the physical sensor 3 including such a sensor group also measures each measurement element at a predetermined measurement cycle determined for each measurement element, and wirelessly communicates the measured data at a predetermined time interval. It has a function to transmit.
- the voltage and current change at very short time intervals. For example, experience has shown that large changes in voltage and current are observed when static electricity is applied. And in order to catch such a change in voltage / current, it is necessary to measure at intervals of at least 10 nanoseconds. On the other hand, there is a need to measure the fluctuation of the control power supply voltage and the fluctuation of the current consumption in the steady state of the electronic control device or the like at a relatively long time interval of about 10 milliseconds.
- a sensor with a relatively long measurement period of about 10 milliseconds and a sensor with a very short measurement period of about 10 nanoseconds are used for sensors that measure voltage and current. Two types should be installed. On the other hand, it has been found from experience that electromagnetic waves and static electricity change at a very fast frequency. Therefore, the measurement period for these elements is preferably about 10 nanoseconds.
- the configuration of the sensor constituting the physical sensor 3 will be described in detail.
- sensor units called probes for measuring these elements are widely available on the market. These probes output the measurement result of each measurement element as an electrical signal. Therefore, by combining these probes with a part for receiving an electrical signal output from the probe, a wireless communication device, which will be described in detail later, and an MPU (Micro Proceding Unit) and a memory, an electronic control device and the like are incorporated.
- MPU Micro Proceding Unit
- a small sensor that can be installed can be easily configured.
- a wireless server 4 that collects measurement data transmitted from these environmental sensors 2 and physical sensors 3 by wireless communication is installed in the company of the diagnosis requester (Company A 1a, Company B 1b and Company C 1c). Yes.
- the wireless server 4 is disposed within approximately 10 meters from the environment sensor 2 and the physical sensor 3.
- a plurality of wireless servers 4 are provided as necessary depending on the number of installed environmental sensors 2 and physical sensors 3, the installation location, and the like.
- a standardized power saving wireless, IEEE 802.15 or the like is used as a method of wireless communication between the environment sensor 2 and the physical sensor 3 and the wireless server 4.
- a standardized power saving wireless, IEEE 802.15 or the like is used.
- infrastructures such as small communication modules are already commercially available. For this reason, it is possible to reduce the size of each sensor used in the environment sensor 2 and the physical sensor 3, and it is also possible to realize high communication quality without new technical development.
- Each diagnosis requester (Company A 1a, Company B 1b and Company C 1c) is provided with a first LAN 5a as an in-house communication network.
- the wireless server 4 is connected to the first LAN 5a.
- the wireless server 4 has a function of transmitting measurement data collected from the environment sensor 2 and the physical sensor 3 to the first LAN 5a at predetermined time intervals.
- a diagnosis client 6 is installed in each diagnosis requester (Company A 1a, Company B 1b, and Company C 1c).
- the diagnosis client 6 is connected to the first LAN 5a of each diagnosis requester. Then, the measurement data transmitted from one or a plurality of wireless servers 4 via the first LAN 5a is collected.
- Each diagnosis requester (1a, 1b, 1c) is communicably connected to the maintenance company 8 via the Internet 7.
- the maintenance company 8 is a diagnostic practitioner who monitors and diagnoses the electronic control device of each diagnostic client.
- the diagnosis client 6 of each diagnosis requester (1a, 1b, 1c) is also connected to the Internet 7 which is an external network when viewed from each diagnosis requester.
- the maintenance company 8 is provided with a diagnosis server 9, which is also connected to the Internet 7.
- the diagnostic client 6 of each diagnostic requester (1a, 1b, 1c) transmits the collected measurement data to the diagnostic server 9 of the maintenance company 8 via the Internet 7 at a predetermined time interval.
- the diagnostic server 9 receives the measurement data of the environmental sensor 2 and the physical sensor 3 transmitted from the diagnostic client 6 via the Internet 7.
- the diagnosis server 9 Upon receiving the measurement data, the diagnosis server 9 stores the received measurement data in the data storage device 10 and analyzes the received measurement data to diagnose the target. In addition to creating a report of diagnosis results, if there is a problem, determine how to deal with the problem. Then, the diagnosis server 9 transmits the diagnosis result report and the coping method to the diagnosis client 6 via the Internet 7 at a predetermined time interval or whenever there is a request from the diagnosis client 6. .
- the maintenance company 8 is provided with a knowledge database 11 that is communicably connected to the diagnosis server 9 by the second LAN 5b installed in the maintenance company 8.
- the knowledge database 11 stores an inference engine, a diagnosis algorithm, and failure correlation data necessary for analysis and diagnosis of an object by the diagnosis server 9.
- the analysis / diagnosis based on the measurement data of the environmental sensor 2 and the physical sensor 3 by the diagnostic server 9 described above is performed with reference to the contents of the knowledge database 11. Further, the diagnosis server 9 updates the contents of the knowledge database 11 as necessary.
- the diagnosis by the diagnosis server 9 is performed as follows.
- a threshold is set in advance for each measurement element of the environmental sensor 2 and the physical sensor 3. And it is judged whether these data are abnormal by comparing measurement data and this threshold value. Further, based on the temperature, humidity, and corrosive gas concentration measured by the environmental sensor 2, for example, the environmental pollution degree and the metal corrosion degree are estimated by a known method as described in Patent Document 1, and the metal part Predict life.
- the inference engine, diagnosis algorithm, and failure correlation data in the knowledge database 11 and the environmental data and physical data measured by the environmental sensor 2 and the physical sensor 3 are used to perform a deterioration diagnosis of the electronic control device and the like.
- the inference engine and the diagnostic algorithm can be configured with known ones as described in Patent Document 2, for example. That is, there are no limitations on implementation methods such as independent logic groups, independent inference engines, and direct execution expressions on algorithms.
- the first LAN 5a of each diagnosis requester (1a, 1b, 1c), the second LAN 5b of the maintenance company 8, and the Internet 7 can be constructed by general-purpose technology.
- environmental measurement and environmental diagnosis for an electronic control device or the like are performed as follows.
- the environmental sensor 2 and the physical sensor 3 are installed in a target electronic control device or the like, and the wireless server 4 and the diagnostic client 6 are installed according to the scale of the target.
- the diagnosis server 9 and the knowledge database 11 are installed in the maintenance company 8, and the diagnosis client 6 and the diagnosis server 9 are connected via the Internet 7.
- the installation of each device constituting the system is thus completed, the environmental sensor 2 and the physical sensor 3 are switched on.
- the environmental sensor 2 and the physical sensor 3 measure each measurement element at the predetermined measurement cycle described above, and transmit the measured data to the wireless server 4 by wireless communication at predetermined time intervals.
- the wireless server 4 collects the measurement data transmitted from the environmental sensor 2 and the physical sensor 3, and transmits the collected measurement data to the diagnostic client 6 via the first LAN 5a at a predetermined time interval.
- the diagnostic client 6 collects the measurement data transmitted from the wireless server 4 via the first LAN 5a, and the collected measurement data is sent to the diagnostic server 9 of the maintenance company 8 via the Internet 7 at a predetermined time interval. Send.
- the diagnostic server 9 receives the measurement data transmitted from the diagnostic client 6 via the Internet 7 and stores it in the data storage device 10. In addition, based on the received measurement data of the environmental sensor 2 and the physical sensor 3, the diagnosis requester (A company 1a, B company 1b, and C company 1c) can be diagnosed by referring to the knowledge database 11. carry out. Then, the diagnosis server 9 creates a report of diagnosis results, and determines a coping method when a problem is found as a result of diagnosis.
- diagnosis server 9 transmits the diagnosis result report and the coping method to the diagnosis client 6 via the Internet 7 at a predetermined time interval or whenever there is a request from the diagnosis client 6.
- the diagnosis client 6 is provided with an output device such as a display or a printer.
- the diagnosis client 6 sends a diagnosis result report sent from the diagnosis server 9 via the Internet 7 and a coping method to this output device. Present to the user via
- the automatic remote monitoring diagnosis system as described above, measurement, data transmission, and diagnosis are constantly performed, and a constant monitoring state is realized. For this reason, even for problems that occur suddenly or sporadically in the electronic control device that is the subject of monitoring, the measurement data at the time of such problems can be stored and analyzed, and the cause can be identified and addressed. It is possible to present.
- the functions of the automatic remote monitoring and diagnosis system as described above are provided to the user as follows.
- this system is configured using IT technology such as wireless communication, the Internet, and a server / client system. Therefore, it is possible to provide various services using such IT technology.
- IT technology such as wireless communication, the Internet, and a server / client system. Therefore, it is possible to provide various services using such IT technology.
- the following can be considered as maintenance / maintenance services that can be provided to the user by the automatic remote monitoring diagnosis system according to the present invention.
- a diagnosis requester who is a user selects a service that he / she needs from the following services, and pays the price to the diagnosis executor to establish a business.
- Environmental data storage Environmental diagnosis and preparation of environmental diagnosis report ⁇ Presentation of countermeasures based on environmental diagnosis report ⁇ Identification of causes in case of sudden or sporadic problems and presentation of countermeasures for the problems ⁇ Implementation of deterioration diagnosis and preparation of deterioration diagnosis report-Presentation of countermeasures based on deterioration diagnosis report-Presentation of maintenance measures
- the sensors, clients, servers, and other devices constituting the automatic remote monitoring and diagnosis system as described above may be installed in advance when a new electronic control device is shipped, or are already in operation. You may install in an electronic controller etc. later.
- the automatic remote monitoring and diagnosis system configured as described above includes an environmental sensor that measures environmental data related to an installation environment of an electronic control device or the like at a predetermined measurement cycle, and transmits the measurement data by wireless communication, an electronic control device, and the like Measuring physical data according to a predetermined measurement cycle, collecting measurement data transmitted by wireless communication, measurement data transmitted from the environment sensor and physical sensor by wireless communication, and collecting the collected measurement data to a predetermined A wireless server that transmits at time intervals and a wireless server that is communicably connected to the first LAN, which is the first communication network, collect measurement data transmitted from the wireless server via the first LAN, and collect A diagnostic client for transmitting the measured data at a predetermined time interval, and the diagnostic client and the second communication network -Communicatively connected via the Internet, receives measurement data sent from the diagnostic client via the Internet, performs diagnosis of electronic control unit etc.
- a data storage device that stores data, and a knowledge database that stores information necessary for the diagnosis server to perform diagnosis, and the diagnosis server sends a diagnosis result to the diagnosis client via the second communication network.
- FIG. FIG. 2 relates to Embodiment 2 of the present invention and is a diagram for explaining the overall configuration of an automatic remote monitoring diagnosis system.
- the second embodiment described here pays particular attention to the storage and provision of measured environmental data in the first embodiment described above.
- the diagnosis client 6 and the diagnosis server 9 are communicably connected via the Internet 7 as shown in FIG. . Therefore, measurement data can be transmitted continuously from the diagnostic client 6 to the diagnostic server 9 at predetermined time intervals. For this reason, it is possible to continuously store measurement data from the start of data measurement to the present in the data storage device 10 on the diagnosis server 9 side.
- the company A 1a who is the measurement / diagnosis requester operates the diagnosis client 6 of the company A 1a and sends a request specifying the items and period of necessary environmental data to the diagnosis server 9.
- the diagnostic server 9 retrieves the designated data from the data storage device 10 based on the content of the request, and transmits the data to the requested diagnostic client 6 via the Internet 7. Then, the diagnostic client 6 displays the environmental data transmitted from the diagnostic server 9 to the user using the output device.
- the communication between the diagnostic client 6 and the diagnostic server 9 uses the Internet 7, it is necessary to consider the confidentiality and security of the communication contents. Therefore, in communication between the diagnostic client 6 and the diagnostic server 9, authentication using an ID and a password may be performed, or information may be encrypted using an encryption technique such as SSL.
- diagnosis server 9 may have a function of collecting data every arbitrary period such as daily report, monthly report, annual report, and the like, and may further have a function of outputting the collected data as an electronic file.
- Other configurations are the same as those of the first embodiment, and detailed description thereof is omitted.
- the automatic remote monitoring / diagnostic system configured as described above has an effect that the diagnosis requester does not need the work that requires the labor of measurement, but also does not require the work of storing data.
- the diagnosis requester can obtain environmental measurement data for an arbitrary period when necessary by operating the diagnosis client.
- the diagnosis server is equipped with a function for collecting data every arbitrary period such as daily report, monthly report, annual report, etc., and by outputting the collected data as an electronic file, Maintenance data can be provided.
- the environmental diagnosis client can easily manage the measurement work and the measurement data, and is free from the trouble of storage.
- FIG. 3 relates to Embodiment 3 of the present invention and is a diagram for explaining the overall configuration of the automatic remote monitoring diagnosis system.
- the third embodiment described here is the same as the first embodiment described above, in particular, the execution of environmental diagnosis and the creation of an environmental diagnosis report, the presentation of countermeasures based on the environmental diagnosis report, and sudden and sporadic. It focuses on the identification of the cause when a problem occurs and the presentation of a method for dealing with the problem.
- the diagnosis server 9 performs diagnosis based on the measurement data transmitted from the diagnosis client 6 via the Internet 7.
- Environmental diagnosis of the electronic control device etc. possessed by the client can be carried out.
- the environmental diagnosis uses a threshold set in the diagnosis server 9 as described above, an inference engine implemented in the knowledge database 11, and the like.
- the diagnostic server 9 continuously stores measurement data from the start of data measurement to the present. For this reason, by using this stored data, environmental diagnosis of electronic control devices, etc. is carried out at arbitrary timings at arbitrary timings, and the results are compiled into a predetermined report format. Can be created. At this time, the period and timing for carrying out the environmental diagnosis may be determined in advance between the company A 1a as the diagnosis requester and the maintenance company 8 as the diagnosis operator.
- the diagnosis requester may operate the diagnosis client 6 to request the diagnosis server 9 for environmental diagnosis at an arbitrary timing.
- the diagnosis server 9 Upon receiving this environmental diagnosis request, the diagnosis server 9 performs environmental diagnosis using the measurement data stored in the data storage device 10, and creates an environmental diagnosis report from the result.
- the diagnosis server 9 transmits this environmental diagnosis report to the diagnosis client 6 via the Internet 7. Then, the diagnosis client 6 displays the environmental diagnosis report transmitted from the diagnosis server 9 to the user using the output device.
- the diagnosis server 9 detects a failure of the electronic control device or the like of the diagnosis requester based on the measurement data transmitted from the diagnosis client 6 via the Internet 7. can do. Then, the cause of the failure can be estimated or specified, and a countermeasure method for the failure can be determined. Note that, as described above, the threshold set in the diagnosis server 9 or the failure correlation data implemented in the knowledge database 11 is used for detecting the failure and estimating the cause thereof.
- a coping method when a problem such as a failure to be monitored is recognized can be immediately presented to the diagnosis requester (Company A 1a) via the Internet 7. Even if the service contract between the requester and the practitioner is not made in advance until the presentation of the coping method, the diagnostic requester operates the diagnostic client 6 to present the coping method at an arbitrary timing. It may be possible to request.
- the diagnostic server 9 obtains measurement data from the environmental sensor 2 and the physical sensor 3 in the electronic control device of the diagnosis requester in real time. Therefore, when a problem occurs suddenly or sporadically in an electronic control device or the like, the cause is identified immediately by analyzing the data at the time of the problem occurrence, and presented to the diagnosis client 6 of the diagnosis requester via the Internet 7. Can do.
- the diagnosis requester operates the diagnosis client 6 even for a client who does not have a service contract for identifying a cause or presenting a countermeasure for such a sudden or sporadic problem with the practitioner in advance. You may enable it to request
- the diagnosis server 9 may always store the environmental diagnosis results, the cause identification results, and the countermeasures in the data storage device 10 or the like.
- the service request from the client side and the service provision from the client side described above may be performed through the financial institution 12 connected to the Internet 7.
- the financial institution 12 connected to the Internet 7.
- it is possible to secure confidentiality and security of information by using an online credit card authentication service or the like possessed by the financial institution 12.
- Other configurations are the same as those of the first embodiment, and detailed description thereof is omitted.
- the diagnosis requester can obtain environmental diagnosis results in real time when necessary. Moreover, the coping method of own equipment can be obtained in real time, and it is possible to obtain the coping method immediately when a problem occurs.
- Embodiment 4 described here focuses on implementation of deterioration diagnosis, creation of a deterioration diagnosis report, and presentation of a coping method based on the deterioration diagnosis report in Embodiment 1 described above.
- the configuration of the automatic remote monitoring and diagnosis system in this embodiment is the same as that in the third embodiment except for the points described below, and will be described with reference to FIG.
- the automatic remote monitoring diagnosis system as described in the second embodiment, measurement data from the start of data measurement until the present is continuously stored in the data storage device 10. Saved. Therefore, it is possible to easily observe time-series changes in measurement data. Then, by observing time-series changes in the measurement data, it is possible to carry out deterioration diagnosis of the electronic control device or the like that is the monitoring target. Furthermore, it is possible to create a deterioration diagnosis report by collecting the results of deterioration diagnosis in a predetermined report format. Specifically, for example, the deterioration of the control power supply can be determined by checking the time-series change of spike noise based on the voltage measurement data among the measurement data obtained by the physical sensor 3.
- the diagnosis requester may operate the diagnosis client 6 and request the diagnosis server 9 for deterioration diagnosis at an arbitrary timing.
- the diagnosis server 9 that has received the request for the deterioration diagnosis performs the deterioration diagnosis using the measurement data stored in the data storage device 10 and creates a deterioration diagnosis report from the result.
- the diagnosis server 9 transmits this deterioration diagnosis report to the diagnosis client 6 via the Internet 7.
- the diagnosis client 6 displays the deterioration diagnosis report transmitted from the diagnosis server 9 to the user using the output device.
- a coping method when a problem is recognized can be immediately presented to the diagnosis requester via the Internet 7. Even if the service contract between the requester and the practitioner is not made in advance until the presentation of the coping method, the diagnostic requester operates the diagnostic client 6 to present the coping method at an arbitrary timing. It may be possible to request.
- the deterioration diagnosis request and the deterioration diagnosis result may be sent through the financial institution 12 connected to the Internet 7 as in the third embodiment.
- the financial institution 12 connected to the Internet 7 as in the third embodiment.
- the data storage device 10 of the diagnosis server 9 can accumulate past measurement data, environmental diagnosis results, and deterioration diagnosis results for each diagnosis requester's equipment. Then, based on these data, it is possible to examine and determine the implementation contents at the time of periodic inspection of the equipment, that is, to implement an equipment inspection consultant. Specifically, for example, power supply replacement can be proposed if deterioration of the control power supply is recognized. Further, if an increase in the noise amount of the AC power supply is recognized, an additional filter can be proposed, and if the humidity tends to decrease, installation of a humidifier can be proposed.
- the diagnosis requester can obtain the deterioration diagnosis result in real time when necessary.
- the diagnosis requester can obtain a coping method in real time when the own equipment deteriorates. Furthermore, it contributes to the improvement of the lifetime of the electronic control unit or the like.
- Embodiment 5 In the fifth embodiment described here, it is possible to detect abnormalities in the devices on the diagnosis requester side constituting the system, such as sensors, wireless servers, and diagnosis clients, in the first embodiment described above. Is.
- measurement data is continuously transmitted from the diagnostic client 6 to the diagnostic server 9 at predetermined time intervals. .
- the diagnostic server 9 monitors whether or not the measurement data is missing, and if the missing data is detected in the measurement data from the diagnostic client 6, the diagnostic requester's diagnostic client 6 sends a device on the diagnosis target side. Specifically, it can be determined that some abnormality has occurred in the environmental sensor 2, the physical sensor 3, the wireless server 4, the first LAN 5a, the diagnostic client 6, and the like.
- the diagnosis server 9 can determine that this is an abnormality of the environmental sensor 2 or the physical sensor 3 by using the knowledge database 11. .
- the diagnosis server 9 transmits a signal to that effect to the diagnosis client 6 via the Internet 7 and issues an alarm in the diagnosis client 6 that has received this signal. It may be.
- an abnormality detection function can be provided not only in the diagnosis server 9 but also in the wireless server 4 and the diagnosis client 6 on the diagnosis requester side. That is, the environmental sensor 2 and the physical sensor 3 and the wireless server 4, and the wireless server 4 and the diagnostic client 6 each continuously communicate measurement data at regular time intervals. Accordingly, when communication with each communication partner is interrupted in the wireless server 4 or the diagnostic client 6, it is possible to detect that an abnormality such as a failure has occurred in the device on the communication partner side. For example, when an abnormality is detected by the diagnostic client 6, it is possible to detect an abnormality in the environmental sensor 2, the physical sensor 3, the wireless server 4, and the like.
- the wireless server 4 and the diagnostic client 6 that have detected that an abnormality has occurred in the communication partner device may issue an alarm to that effect, or their own upper device (wireless server). If it is 4, the diagnosis client 6 and the diagnosis server 9 may be notified, and if it is the diagnosis client 6, it may be notified to the diagnosis server 9).
- the diagnostic operator can provide a highly reliable measurement system to the environmental diagnostic client.
- FIG. 4 and 5 relate to Embodiment 6 of the present invention
- FIG. 4 is a diagram for explaining the overall configuration of the automatic remote monitoring diagnostic system
- FIG. 5 shows another example of the automatic remote monitoring diagnostic system in this embodiment. It is a figure explaining the whole structure.
- the first embodiment described above has a configuration in which measurement data of a plurality of different diagnosis requesters are collectively managed and collectively diagnosed by a diagnosis server of a diagnosis performer such as a manufacturer or a maintenance service company. For this reason, the Internet is used for communication between a plurality of diagnosis requesters and a diagnosis practitioner.
- the sixth embodiment described here does not change the configuration of the devices constituting the first embodiment and the remote monitoring system, in other words, the configuration of the network nodes, and maintains the communication network between the devices. It shows an example of changing according to the situation / state of the monitoring target / diagnosis requester.
- company A as a diagnosis requester monitors electronic control devices, etc., in multiple sites (factories) of the company, and manages and diagnoses data at the headquarters of the company. It is an example of the structure made to perform.
- the electronic control devices and the like to be monitored exist in each of the A company A factory 1d, the A company B factory 1e, and the A company C factory 1f.
- the environmental sensor 2 and the physical sensor 3 are installed for every electronic control apparatus etc. of each factory. Measurement data is transmitted from the environmental sensor 2 and the physical sensor 3 to the wireless server 4 by wireless communication.
- the communication network that connects the wireless server 4 and the diagnostic client 6 so as to be communicable is the first LAN 5a laid in each factory.
- a company A factory 1d, A company B factory 1e, A company C factory 1f, and A company (head office) 1g are connected by an intranet 13 which is an in-house LAN that can be communicated only within A company.
- the intranet 13 is a communication network that connects each diagnostic client 6 installed in each factory in the company A and a diagnostic server 9 installed in the company A (head office) 1g so as to communicate with each other.
- a communication network that connects the diagnosis server 9 and the knowledge database 11 in the company A (head office) 1g so as to communicate with each other is the second LAN 5b.
- Other configurations are the same as those in the first embodiment.
- FIG. 5 shows an electronic control device, etc., in an in-house factory 1h, which is a certain site (factory) of Company A as a diagnosis requester, and data management and diagnosis are also performed on the same site.
- an in-house factory 1h which is a certain site (factory) of Company A as a diagnosis requester, and data management and diagnosis are also performed on the same site.
- the electronic control device and the like in the A in-house factory 1h are monitored, and the environmental sensor 2, the physical sensor 3, the wireless server 4, and the diagnostic client 6 are installed in the A in-house factory 1h.
- a diagnosis server 9, a data storage device 10, and a knowledge database 11 are also installed in the A company factory 1h.
- Measurement data is transmitted from the environmental sensor 2 and the physical sensor 3 to the wireless server 4 by wireless communication.
- a first LAN 5a is laid in the in-house factory 1h.
- the communication network that connects the wireless server 4 and the diagnostic client 6 so as to communicate with each other is the first LAN 5a.
- the communication network that connects the diagnostic client 6 and the diagnostic server 9 to be communicable is also the first LAN 5a.
- the communication network that connects the diagnostic server 9 and the knowledge database 11 so as to communicate with each other is also the first LAN 5a. That is, the wireless server 4, the diagnostic client 6, the diagnostic server 9, and the data storage device 10 are all connected by the first LAN 5a that is the same communication network. Other configurations are the same as those in the first embodiment.
- the automatic remote monitoring and diagnosis system configured as described above appropriately changes the communication network that connects these devices so that they can communicate without changing the basic configuration of the devices that make up the system such as sensors, clients, and servers. By doing so, it is possible to construct flexibly according to the situation / state of the monitoring target / diagnosis requester.
- a closed system of only the diagnosis requester can be constructed. At this time, the system can be flexibly constructed according to the position and number of the monitoring targets of the diagnosis requester.
- FIG. 4 shows a case where a factory with an electronic control device or the like to be monitored is a diagnosis requester scattered in various places.
- FIG. 5 shows a case of a diagnosis requester who has only one location of a factory with an electronic control device or the like to be monitored.
- all the devices constituting the system are arranged only in one place in the factory. Therefore, environmental data can be measured and diagnosed by closing only in the factory, and measurement data in the factory does not leak outside the factory.
- the diagnosis operator who is requested to diagnose the measurement data of the electronic control devices and the like in all the places where the diagnosis is actually performed does not bother manpower. It can be collected automatically and easily. For this reason, it is possible to reduce the burden of management and the burden of diagnosis work on the diagnostic practitioner.
- improvement of the inference engine, diagnosis algorithm, and fault correlation data can be expected. That is, it contributes to the advancement of the knowledge database, and as a result, the cause identifying ability can be improved, which is beneficial to both the diagnosis requester and the diagnosis practitioner.
- the present invention can be used for an automatic remote monitoring diagnosis system that monitors the state of an electronic control device for plant equipment or the state of equipment such as a plant and automatically diagnoses the presence or absence of abnormality.
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Abstract
Description
図1は、この発明の実施の形態1に係るものである。この図1は、自動遠隔監視診断システムの全体構成を示すものである。図において1a、1b及び1cは、それぞれ電子制御装置等の状態の診断依頼者であるA社、B社及びC社である。なお、ここでは、診断依頼者の数は3であるとしているが、特にいくつであっても構わない。これらのA社1a、B社1b及びC社1cには、本願発明に係る自動遠隔監視診断システムの監視・診断対象である電子制御装置等(図示せず)が備えられている。そして、これらの診断依頼者の、電子制御装置等の筐体内や電子制御装置等の周辺には、環境センサー2及び物理センサー3が設置されている。
まず、対象となる電子制御装置等に環境センサー2及び物理センサー3を設置し、無線サーバー4及び診断クライアント6を対象の規模に応じて設置する。診断サーバー9及び知識データベース11を保全会社8に設置し、診断クライアント6と診断サーバー9とをインターネット7を介して接続する。こうしてシステムを構成する各機器の設置が完了したら、環境センサー2及び物理センサー3のスイッチを投入する。
・環境診断の実施と環境診断報告書の作成
・環境診断報告書に基づく対処方法の提示
・突発的、散発的問題発生時の原因特定及び当該問題への対処方法の提示
・劣化診断の実施と劣化診断報告書の作成
・劣化診断報告書に基づく対処方法の提示
・保全施策の提示
図2は、この発明の実施の形態2に係るもので、自動遠隔監視診断システムの全体構成を説明する図である。
ここで説明する実施の形態2は、前述した実施の形態1において、特に、測定した環境データの保管及びその提供に着目したものである。
他の構成については実施の形態1と同様であって、その詳細説明は省略する。
図3は、この発明の実施の形態3に係るもので、自動遠隔監視診断システムの全体構成を説明する図である。
ここで説明する実施の形態3は、前述した実施の形態1において、特に、環境診断の実施と環境診断報告書の作成、環境診断報告書に基づく対処方法の提示、並びに、突発的、散発的問題発生時の原因特定及び当該問題への対処方法の提示に着目したものである。
他の構成については実施の形態1と同様であって、その詳細説明は省略する。
ここで説明する実施の形態4は、前述した実施の形態1において、特に、劣化診断の実施と劣化診断報告書の作成及び劣化診断報告書に基づく対処方法の提示に着目したものである。なお、この実施の形態における自動遠隔監視診断システムの構成は、これから述べる点を除き実施の形態3と同様であるため、図3を援用して説明する。
ここで説明する実施の形態5は、前述した実施の形態1において、センサー、無線サーバーや診断クライアント等の、本システムを構成する診断依頼者側の機器の異常を検出することができるようにしたものである。
図4及び図5は、この発明の実施の形態6に係るもので、図4は自動遠隔監視診断システムの全体構成を説明する図、図5はこの実施の形態における自動遠隔監視診断システムの別の全体構成を説明する図である。
前述した実施の形態1は、複数の異なる診断依頼者の測定データをメーカーや保守保全サービス会社等の診断実施者の診断サーバーで一括管理、一括診断する構成であった。また、このため、複数の診断依頼者と診断実施者との間の通信にはインターネットを利用した。
なお、他の構成については実施の形態1等と同様である。
なお、他の構成については実施の形態1等と同様である。
1b B社
1c C社
1d A社内A工場
1e A社内B工場
1f A社内C工場
1g A社(本社)
1h A社内工場
2 環境センサー
3 物理センサー
4 無線サーバー
5a 第1のLAN
5b 第2のLAN
6 診断クライアント
7 インターネット
8 保全会社
9 診断サーバー
10 データ保存装置
11 知識データベース
12 金融機関
13 イントラネット
Claims (8)
- 電子制御装置又は機器を診断する自動遠隔監視診断システムにおいて、
前記電子制御装置又は機器の設置環境に係る環境データを所定の測定周期で測定し、測定データを無線通信により送信する環境センサーと、
前記電子制御装置又は機器に係る物理データを所定の測定周期で測定し、測定データを無線通信により送信する物理センサーと、
前記環境センサー及び前記物理センサーから無線通信で送信された測定データを収集し、収集した前記測定データを所定の時間間隔で送信する無線サーバーと、
前記無線サーバーと第1の通信ネットワークにより通信可能に接続され、前記無線サーバーから送信された前記測定データを前記第1の通信ネットワークを介して収集し、収集した前記測定データを所定の時間間隔で送信する診断クライアントと、
前記診断クライアントと第2の通信ネットワークにより通信可能に接続され、前記診断クライアントから送信された前記測定データを前記第2の通信ネットワークを介して受信し、受信した前記測定データに基づいて前記電子制御装置又は機器の診断を実施する診断サーバーと、
前記診断サーバーが受信した前記測定データを保存するデータ保存装置と、
前記診断サーバーが前記診断を実施する際に必要な情報を記憶する知識データベースと、を備え、
前記診断サーバーは、前記診断の結果を前記第2の通信ネットワークを介して前記診断クライアントに送信するとともに、前記診断の結果、前記電子制御装置又は機器に問題がある場合には、この問題への対処方法を決定し、前記対処方法を前記第2の通信ネットワークを介して前記診断クライアントに送信することを特徴とする自動遠隔監視診断システム。 - 前記環境センサー、前記物理センサー、前記無線サーバー及び前記診断クライアントは、前記電子制御装置又は機器の診断を依頼する診断依頼者の自工場内に設置され、
前記診断サーバー、前記データ保存装置及び前記知識データベースは、前記診断を依頼され実施する診断実施者側に設置され、
前記第1の通信ネットワークは、前記診断依頼者の前記自工場内に敷設されたLANであり、
前記第2の通信ネットワークは、インターネットを利用したものであることを特徴とする請求項1に記載の自動遠隔監視診断システム。 - 前記環境センサー、前記物理センサー、前記無線サーバー及び前記診断クライアントは、前記電子制御装置又は機器の診断を依頼する診断依頼者の自工場内に設置され、
前記診断サーバー、前記データ保存装置及び前記知識データベースは、前記診断依頼者の本社に配置され、
前記第1の通信ネットワークは、前記診断依頼者の前記自工場内に敷設されたLANであり、
前記第2の通信ネットワークは、前記診断依頼者の自工場と前記本社とを通信可能に接続するイントラネットであることを特徴とする請求項1に記載の自動遠隔監視診断システム。 - 前記環境センサー、前記物理センサー、前記無線サーバー及び前記診断クライアント、並びに、前記診断サーバー、前記データ保存装置及び前記知識データベースは、前記電子制御装置又は機器の診断を依頼する診断依頼者の自工場内に設置され、
前記第1の通信ネットワーク及び前記第2の通信ネットワークは、ともに、前記診断依頼者の前記自工場内に敷設されたLANであることを特徴とする請求項1に記載の自動遠隔監視診断システム。 - 前記診断サーバーは、前記データ保存装置に保存された前記測定データを所定の期間毎に纏めて電子ファイルとして出力し、この電子ファイルを前記第2の通信ネットワークを介して前記診断クライアントに送信することを特徴とする請求項1から請求項4のいずれかに記載の自動遠隔監視診断システム。
- 前記診断サーバーは、前記診断クライアントから送信された前記測定データを、前記データ保存装置に保存された過去の測定データと比較することにより前記電子制御装置又は機器の劣化を診断し、この劣化の診断結果を所定の報告書形式にまとめ、この報告書形式にまとめた劣化の診断結果を前記第2の通信ネットワークを介して前記診断クライアントに送信するとともに、劣化の診断の結果、前記電子制御装置又は機器に問題がある場合には、この問題への対処方法を決定し、前記対処方法を前記第2の通信ネットワークを介して前記診断クライアントに送信することを特徴とする請求項1から請求項4のいずれかに記載の自動遠隔監視診断システム。
- 前記診断サーバーは、前記診断クライアントから送信された前記測定データに基づいて、前記環境センサー、前記物理センサー、前記無線サーバー及び前記診断クライアントの少なくともいずれかに異常が発生したことを検出し、異常発生を検出した場合には、その旨の信号を前記第2の通信ネットワークを介して前記診断クライアントに送信することを特徴とする請求項1から請求項4のいずれかに記載の自動遠隔監視診断システム。
- 前記診断クライアントは、前記無線サーバーから送信された前記測定データに基づいて、前記環境センサー、前記物理センサー及び前記無線サーバーの少なくともいずれかに異常が発生したことを検出し、異常発生を検出した場合には、その旨のアラームを発することを特徴とする請求項1から請求項4のいずれかに記載の自動遠隔監視診断システム。
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PCT/JP2010/068179 WO2012049771A1 (ja) | 2010-10-15 | 2010-10-15 | 自動遠隔監視診断システム |
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US (1) | US9703754B2 (ja) |
JP (1) | JPWO2012049771A1 (ja) |
KR (1) | KR20130042586A (ja) |
CN (1) | CN103154841B (ja) |
HK (1) | HK1184552A1 (ja) |
TW (1) | TWI448856B (ja) |
WO (1) | WO2012049771A1 (ja) |
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JP2013232191A (ja) * | 2012-04-30 | 2013-11-14 | General Electric Co <Ge> | 工業制御システムに対するセキュリティ事象をロギングするためのシステムおよび方法 |
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CN105229679A (zh) * | 2013-03-15 | 2016-01-06 | 微软技术许可有限责任公司 | 生存周期产品分析 |
CN104932487A (zh) * | 2015-06-04 | 2015-09-23 | 北京交通大学 | 一种地铁车辆远程诊断系统 |
JP2018155675A (ja) * | 2017-03-21 | 2018-10-04 | 株式会社日産アーク | 解析支援システム |
CN112513748A (zh) * | 2018-08-09 | 2021-03-16 | 恩德莱斯和豪瑟尔过程解决方案股份公司 | 自动化现场装置 |
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Also Published As
Publication number | Publication date |
---|---|
CN103154841B (zh) | 2015-11-25 |
US9703754B2 (en) | 2017-07-11 |
KR20130042586A (ko) | 2013-04-26 |
HK1184552A1 (zh) | 2014-01-24 |
US20130185022A1 (en) | 2013-07-18 |
TW201216021A (en) | 2012-04-16 |
CN103154841A (zh) | 2013-06-12 |
JPWO2012049771A1 (ja) | 2014-02-24 |
TWI448856B (zh) | 2014-08-11 |
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