JP7271769B1 - High pressure gas facility monitoring system and high pressure gas facility monitoring method - Google Patents

Abstract

A high-pressure gas facility monitoring system and a high-pressure gas facility monitoring method are provided that reduce the time required to analyze the cause of a trouble occurring in a facility that uses high-pressure gas. A high-pressure gas equipment monitoring system 1 records one or more storages (cylinder cabinets 10) storing gas containers filled with high-pressure gas and the inside of the storages, and generates an event inside the storages. is used as a trigger, the camera 15 sends the recorded data to the recording server with a time stamp, the recording server 20 saves the recorded data sent from the camera, and the recording server saves the recorded data according to the input instructions. and a management server 30, which is a display device for displaying recorded data. [Selection drawing] Fig. 1

Description

The present invention relates to a high-pressure gas equipment monitoring system and a high-pressure gas equipment monitoring method.

High-pressure gas used in gas supply facilities is dangerous and must be handled with due consideration for safety. A container filled with a high-pressure gas (hereinafter referred to as a "gas container") is housed in a cylinder cabinet and used (see, for example, Patent Document 1). In the cylinder cabinet 10, installation of gas containers, change of gas containers to be used, and removal of gas containers are basically performed by workers.

Japanese Patent No. 2501913

As described above, since installation of the gas container, change of the gas container to be used, removal of the gas container, etc. are performed manually, troubles may occur in the container replacement work. Furthermore, gas supply equipment may have troubles such as gas leakage. Conventionally, in order to analyze the cause of such troubles, reconfirmation of work procedures, deterioration of equipment, and confirmation of whether or not maintenance has been performed are performed. Therefore, there is a problem that it takes a lot of time to analyze the cause of trouble.

In view of the above circumstances, it is an object of the present invention to provide a technique capable of shortening the time required to analyze the cause of a trouble occurring in a facility that uses high-pressure gas.

Aspect 1 of the present invention includes one or more storages storing gas containers filled with high-pressure gas, a camera for recording the inside of the storages, and the recorded data inside the storages recorded by the camera is stored. and a display device for displaying recorded data stored in the recording server according to an input instruction.

Aspect 2 of the present invention is the high-pressure gas equipment monitoring system according to Aspect 1, further comprising an assigning unit that assigns a time stamp to recorded data triggered by an event occurring inside the one or more storages, wherein the camera is and transmitting recorded data for a predetermined period including the recorded data to which the time stamp is added by the adding unit as event recorded data to the recording server, and the recording server transmits the event recorded data transmitted from the camera to the recording server. Save as recorded data.

Aspect 3 of the present invention is the high-pressure gas facility monitoring system of aspect 2, wherein the one or more storages notify the display device of event information regarding event occurrence, and the display device receives the notification The event information is displayed, and the event recording data corresponding to the event indicated by the selected event information is displayed.

Aspect 4 of the present invention is the high-pressure gas equipment monitoring system according to aspect 3, wherein the display device requests the recording server for the event recording data corresponding to the event indicated by the selected event information, transmitting a request signal including at least identification information of the camera that recorded the event recording data and information on the time when the event occurred to the recording server, and the recording server selects, from the stored event recording data, event-recorded data recorded by the camera specified by the identification information of the camera included in the request signal, wherein the time indicated by the time information when the event occurred matches the time indicated by the attached time stamp; and event recording data to be provided to the display device.

Aspect 5 of the present invention is the high-pressure gas facility monitoring system according to any one of aspects 1 to 4, wherein the camera has a function of detecting a moving object, and the moving object is detected during work performed inside the storage. The function detects the presence or absence of an abnormality, and the one or more storages issue an alert when an abnormality is detected by the camera.

A sixth aspect of the present invention is the high-pressure gas equipment monitoring system according to any one of the first to fifth aspects, wherein the camera captures information on heat inside the storage chamber obtained by a heat sensor that detects heat. It has a function to display the temperature distribution on the image by synthesizing it with the captured image, or a function to detect heat, and the presence or absence of ignition inside the storage is detected based on the results obtained from either function. , the one or more receptacles generate an alert when a fire is detected by the camera.

Aspect 7 of the present invention is the high-pressure gas facility monitoring system according to any one of aspects 1 to 6, further comprising a cylinder transport truck for transporting the gas container, and the one or more storages are cylinder cabinets. The camera has a moving object detection function, detects whether or not the cylinder transport cart and the cylinder cabinet are connected by the moving object detection function, and the cylinder cabinet detects the cylinder by the camera. An alert is issued when it is determined that the carriage for transportation and the cylinder cabinet are not connected.

Aspect 8 of the present invention is the high-pressure gas facility monitoring system according to any one of aspects 1 to 7, further comprising a cylinder transport truck for transporting the gas container, and the one or more storages are cylinder cabinets. wherein the camera has a moving body detection function, detects whether or not the cylinder transport cart is positioned in front of the cylinder cabinet by the moving body detection function, and the cylinder cabinet detects the cylinder transport When it is determined that the truck is positioned in front of the cylinder cabinet, the door is opened.

A ninth aspect of the present invention is the high-pressure gas facility monitoring system according to any one of aspects 1 to 8, wherein the camera has a moving object detection function, detects a user's movement by the moving object detection function, and One or more repositories cause processing to be executed in response to the detected movement of the user.

One aspect of the present invention records the inside of one or more storages containing gas containers filled with high-pressure gas, saves the recorded data inside the recorded storages, and responds to input instructions. , a high-pressure gas installation monitoring method for displaying stored recorded data.

According to the present invention, it is possible to shorten the time required to analyze the cause of a trouble occurring in a facility that uses high-pressure gas.

BRIEF DESCRIPTION OF THE DRAWINGS It is a figure which shows the structural example of the high pressure gas equipment monitoring system in embodiment. It is a figure which shows an example of a structure of the recording server in embodiment. It is a figure which shows an example of a structure of the management server in embodiment. It is a figure which shows an example of the container table in embodiment. It is a figure which shows an example of the management table in embodiment. FIG. 10 is a diagram showing an example of a display image displayed when a monitoring application is activated; FIG. FIG. 4 is a diagram showing an example of a display image for monitoring the state inside the cylinder cabinet in real time; FIG. 10 is a diagram showing an example of a display image for monitoring the state inside the cylinder cabinet when an event occurs; FIG. 4 is a sequence diagram showing the flow of recording data storage processing of the high-pressure gas equipment monitoring system in the embodiment; It is a sequence diagram showing the flow of processing of the high-pressure gas equipment monitoring system in the embodiment.

An embodiment of the present invention will be described below with reference to the drawings.

FIG. 1 is a diagram showing a configuration example of a high-pressure gas equipment monitoring system 1 according to an embodiment. The high-pressure gas facility monitoring system 1 is a system that monitors the inside of facilities that use high-pressure gas, such as gas supply facilities. A high-pressure gas facility monitoring system 1 includes a plurality of cylinder cabinets 10 , a recording server 20 and a management server 30 . A plurality of cylinder cabinets 10 , recording servers 20 and management servers 30 are communicably connected via a network 40 . The network 40 is a LAN (Local Area Network).

In the following explanation, it is assumed that the plurality of cylinder cabinets 10, the recording server 20 and the management server 30 are installed in one customer's facility such as one factory. That is, in the following description, the high-pressure gas equipment monitoring system 1 will be used to monitor abnormalities within one facility.

The cylinder cabinet 10 is equipment for supplying the high-pressure gas filled in the gas container B to the semiconductor manufacturing apparatus, and is a container for storing a plurality of gas containers B in one cylinder cabinet 10 . The cylinder cabinet 10 opens and closes a door, and stores a pair of gas containers B side by side in the width direction in a storage space inside thereof. In the cylinder cabinet 10, by replacing one of the gas containers B while the gas is being supplied from one of the gas containers B, the other gas container B can be replaced without interrupting the gas supply. there is

In addition to this, the cylinder cabinet 10 includes, for example, piping connected to the gas container B, a control box containing devices for opening and closing the door, opening and closing the valve, monitoring pressure, monitoring gas leakage, etc. 12 and a piping box (not shown) containing piping for connecting to semiconductor manufacturing equipment and the like. The control box 12 is provided with a control device such as a PLC (Programmable Logic Controller) and a communication unit for communicating with the management server 30. The communication unit receives door opening/closing information, valve opening/closing information, and pressure information. Container information such as monitoring results, gas leakage monitoring results, and information on the remaining amount of the gas container B is transmitted to the management server 30 .

Furthermore, the cylinder cabinet 10 notifies the management server 30 of event information indicating that an event has occurred, using the occurrence of an event as a trigger. Here, the event means work performed in the facility (for example, start of replacement work of gas container B), trouble occurring in the work (for example, mistaken replacement of gas container B), occurrence after work or regardless of work. This includes problems that may occur (for example, gas leaks and fires). The event information includes information such as the identification information of the cylinder cabinet 10, the time information when the event occurred, the content of the event that occurred, the tag, and the device name.

Cylinder cabinet 10 is equipped with one or more cameras 15 . Camera 15 records the inside of cylinder cabinet 10 . Camera 15 is, for example, a network camera. Since the cylinder cabinet 10 contains combustible high-pressure gas, it is preferable that electric parts are not exposed as much as possible. Therefore, the camera 15 is desirably a dome-shaped network camera, and is installed so that only the lens portion protrudes into the cylinder cabinet 10 . Power is supplied to the camera 15 using PoE (Power over Ethernet (registered trademark)).

The camera 15 transmits time-series recorded data (hereinafter referred to as “real-time recorded data”) obtained by continuously photographing the inside of the cylinder cabinet 10 to the recording server 20 via the network 40 . Furthermore, the camera 15 adds a time stamp to the recorded data, triggered by the occurrence of an event detected by the control device of the cylinder cabinet 10 or by the camera itself. The time given as the time stamp is the time indicated by the event occurrence time information included in the event information by the cylinder cabinet 10 . As a result, the event occurrence time notified to the management server 30 can be associated with the recorded data at the time of the event occurrence. As described above, the camera 15 includes at least a photographing unit that photographs the inside of the cylinder cabinet 10 , an imparting unit that imparts a time stamp, a communication unit that transmits recorded data, and a control unit that controls the camera 15 .

The camera 15 transmits recorded data for a predetermined period (hereinafter referred to as “event recorded data”) including recorded data with time stamps to the recording server 20 via the network 40 . Here, the event recording data is recording data including images before and after the occurrence of the event. That is, the event recording data includes not only the recording data when the event occurs, but also the recording data from a predetermined period before the event occurrence (for example, a few seconds before the event occurs) to the time when the event occurs. Recorded data for a predetermined period after the occurrence of the event (for example, several seconds after the occurrence of the event). It should be noted that how long the storage period of the event recording data is before the event occurs and the period after the event occurs is set in advance.

The camera 15 may be provided with any one of a moving object detection function, a sound collection function, an audio output function, and a heat detection function. When the camera 15 has a moving body detection function, the camera 15 detects the presence or absence of an abnormality in the work performed inside the cylinder cabinet 10 by the moving body detection function. An abnormality in the work performed inside the cylinder cabinet 10 is, for example, when a worker touches a gas container B different from the gas container B to be replaced (for example, a gas container B supplying high-pressure gas). or when a tool irrelevant to the work is detected. In the cylinder cabinet 10, it is known which of the gas containers B stored therein is supplying the high-pressure gas. Therefore, based on the operator's hand detected by the moving body detection function and the information from the cylinder cabinet 10 (information indicating which gas container B is supplying the high pressure gas), the camera 15 replaces When it is determined that the operator touches a gas container B different from the gas container B to be handled, it is determined that an abnormality has occurred in the work being performed inside the cylinder cabinet 10 . When it is determined by the camera 15 that an abnormality has occurred in the work performed inside the cylinder cabinet 10, the cylinder cabinet 10 issues an alert. As a result, it is possible to call attention to the worker before an erroneous work is performed. In this case, the camera 15 may transmit event recording data to the recording server 20 .

When the camera 15 has a function of detecting heat (camera thermography function), the camera 15 detects whether or not there is ignition inside the cylinder cabinet 10 based on the detected heat. When the camera 15 determines that a fire has occurred inside the cylinder cabinet 10, the cylinder cabinet 10 issues an alert. In this case, the camera 15 may transmit event recording data to the recording server 20 .

When a thermal sensor for detecting heat is provided inside the cylinder cabinet 10 (for example, together with the camera 15), the camera 15 combines the information on the heat inside the cylinder cabinet 10 obtained by the thermal sensor with the photographed image. By doing so, the temperature distribution may be displayed on the image. A thermal sensor detects far-infrared rays emitted by a heat-source object or organism, and generates a temperature distribution by analyzing the intensity of the far-infrared rays. The temperature distribution is color-coded according to the intensity of far-infrared rays. The camera 15 acquires the temperature distribution as information on the heat inside the cylinder cabinet 10 obtained by the heat sensor. The camera 15 displays the temperature distribution on the image by synthesizing the captured image with the acquired temperature distribution. Then, the camera 15 detects the presence or absence of ignition inside the cylinder cabinet 10 based on the result of displaying the temperature distribution on the image. When the camera 15 determines that a fire has occurred inside the cylinder cabinet 10, the cylinder cabinet 10 issues an alert.

The recording server 20 is a server that stores recording data (real-time recording data and event recording data) transmitted from the camera 15 . The recording server 20 has a large-capacity storage device, and classifies the recorded data transmitted from each camera 15 installed in each cylinder cabinet 10 for each camera 15 and stores them in the storage device. In response to a request from the management server 30, the recording server 20 provides the management server 30 with the requested recorded data from among the recorded data stored in the storage device.

The management server 30 is a device that monitors the inside of the facility. The management server 30 receives various information from the cylinder cabinet 10 (for example, pressure monitoring results, gas leakage monitoring results, information on the remaining amount of the gas container B, and event information). Furthermore, the management server 30 displays the event information notified from the cylinder cabinet 10 as an alert list on the screen. The management server 30 displays recorded data corresponding to the event indicated by the event information selected from the alert list displayed on the screen. The management server 30 is configured using an information processing device such as a personal computer. The management server 30 is one aspect of a display device.

The high-pressure gas facility monitoring system 1 may include a portable communication device that can be carried around by the user. Portable communication devices are, for example, smartphones, tablet terminals, laptop computers, and the like. The portable communication device has the same functions as the management server 30 and performs the same processing. A portable communication device is one aspect of a display device.

FIG. 2 is a diagram showing an example of the configuration of the recording server 20 in the embodiment. Recording server 20 includes communication unit 21 , storage unit 22 , and control unit 23 .

The communication unit 21 communicates with the camera 15 and the management server 30 . For example, the communication unit 21 receives recorded data transmitted from each camera 15 . For example, the communication unit 21 transmits recorded data to the management server 30 .

The storage unit 22 stores regular recording data 221 and event recording data 222 . The constantly recorded data 221 is real-time recorded data transmitted from the camera 15 , for example, time-series recorded data constantly recorded by each camera 15 . The event recording data 222 is event recording data transmitted from the camera 15, such as recording data recorded when an event occurs. The storage unit 32 is configured using a large-capacity storage device such as a magnetic storage device or a semiconductor storage device.

The control unit 23 controls the recording server 20 as a whole. The control unit 23 is configured using a processor such as a CPU (Central Processing Unit) and a memory. The control unit 23 implements the functions of the recording unit 231 and the providing unit 232 by executing programs.

Some or all of the recording unit 231 and the providing unit 232 are implemented by hardware (including circuitry) such as ASIC (Application Specific Integrated Circuit), PLD (Programmable Logic Device), and FPGA (Field Programmable Gate Array). It may be realized, or may be realized by cooperation of software and hardware. The program may be recorded on a computer-readable recording medium. Computer-readable recording media are portable media such as flexible disks, magneto-optical disks, ROMs and CD-ROMs, and non-temporary storage media such as hard disks built into computer systems. The program may be transmitted over telecommunications lines.

Some of the functions of the recording unit 231 and the providing unit 232 do not have to be installed in the recording server 20 in advance, and may be realized by installing an additional application program in the recording server 20 .

The recording unit 231 records the recorded data received by the communication unit 21 in the storage unit 22 . For example, when real-time recorded data is received by the communication unit 21 , the recording unit 231 classifies it for each camera 15 and records it in the constantly recorded data 221 of the storage unit 22 . For example, when event recording data is received by the communication unit 21 , the recording unit 231 classifies the event recording data for each camera 15 and records the event recording data 222 in the storage unit 22 .

The providing unit 232 provides the requested recorded data to the management server 30 in response to a request from the management server 30 . Specifically, when the management server 30 requests the real-time recorded data, the providing unit 232 provides the management server 30 with the real-time recorded data recorded by the designated camera 15 . At this time, the providing unit 232 provides the latest recorded data recorded by the designated camera 15 to the management server 30 in real time. The providing unit 232 provides the requested event recorded data to the management server 30 when the event recorded data is requested from the management server 30 . When retrieving the requested event recorded data, the providing unit 232 refers to the identification information of the camera 15 and the time information included in the request from the management server 30 to determine the shooting source of the requested event recorded data. By identifying the camera 15 and comparing the time indicated by the time information with the time stamp, the requested event recording data is identified.

FIG. 3 is a diagram showing an example of the configuration of the management server 30 in the embodiment. The management server 30 includes a communication section 31 , a storage section 32 , a control section 33 , an operation section 34 and a display section 35 .

The communication unit 31 communicates with the cylinder cabinet 10 and the recording server 20 . For example, the communication unit 31 receives various information and event information from the cylinder cabinet 10 . For example, the communication unit 31 receives recorded data transmitted from the recording server 20 .

The storage unit 32 stores a monitoring application 321 , a container table 322 , a management table 323 and display information 324 . The monitoring application 321 is an application program for monitoring the high pressure gas equipment monitoring system 1 in the management server 30 . When the monitoring application 321 is activated, a dedicated application screen is displayed on the screen of the display unit 35 . The container table 322 is a table in which information about the gas container B is registered. The management table 323 is a table in which information for managing the gas container B is registered. The display information 324 is information to be displayed on the display unit 35, such as information obtained from the cylinder cabinet 10 (for example, various information and event information) and recorded data obtained from the recording server 20. FIG. The storage unit 32 is configured using a storage device such as a magnetic hard disk device or a semiconductor storage device.

The control unit 33 controls the management server 30 as a whole. The control unit 33 is configured using a processor such as a CPU and a memory. The control unit 33 realizes the functions of an acquisition unit 331, a display control unit 332, and a request unit 333 by executing programs.

Some or all of the acquisition unit 331, the display control unit 332, and the request unit 333 may be realized by hardware (including circuitry) such as ASIC, PLD, and FPGA, or software and hardware. may be realized by cooperation of The program may be recorded on a computer-readable recording medium. Computer-readable recording media are portable media such as flexible disks, magneto-optical disks, ROMs and CD-ROMs, and non-temporary storage media such as hard disks built into computer systems. The program may be transmitted over telecommunications lines.

Some of the functions of the acquisition unit 331, the display control unit 332, and the request unit 333 do not need to be installed in the management server 30 in advance, and may be realized by installing an additional application program in the management server 30. good.

The acquisition unit 331 acquires various types of information. For example, the acquisition unit 331 acquires information (for example, various information and event information) obtained from the cylinder cabinet 10 and recorded data obtained from the recording server 20 .

The display control unit 332 activates the monitoring application 321 and controls the display screen of the display unit 35 .

The request unit 333 requests recorded data from the recording server 20 in response to a request input via the operation unit 34 .

The operation unit 34 is configured using existing input devices such as a keyboard, pointing device (mouse, tablet, etc.), touch panel, and buttons. The operation unit 34 is operated by the user when inputting user instructions to the management server 30 . For example, the operation unit 34 receives an instruction to request recording data, an instruction to switch screens, and the like.

The display unit 35 is an image display device such as a liquid crystal display or an organic EL display. The display unit 35 displays various information. The display unit 35 may be an interface for connecting the image display device to the management server 30 . In this case, the display unit 35 generates a video signal for displaying information, and outputs the video signal to the image display device connected thereto.

FIG. 4 is a diagram showing an example of the container table 322 in the embodiment.
In the container table 322, information on the gas name, concentration, quality assurance expiration date, initial filling amount, production date, and remaining amount is registered in association with the container number. The container number represents identification information for identifying the gas container B. FIG. The gas name represents the name of the gas filled in the gas container B. FIG. The concentration represents the concentration of the gas filled in the gas container B. The quality assurance period represents the period during which the quality of the gas filled in the gas container B is guaranteed. The initial filling amount represents the amount of gas filled in the gas container B at the time of delivery. The initial filling amount corresponds to the filling amount in the container information. The production date represents the date when the gas container B was filled with gas. The remaining amount represents the amount of gas remaining in the gas container B. Information on the remaining amount is transmitted from the cylinder cabinet 10 at a predetermined timing.

FIG. 5 is a diagram showing an example of the management table 323 in the embodiment.
In the management table 323, tag identification information, carry-in date, and carry-out date information are registered in association with storage information. Storage information represents information about the cylinder cabinet 10 . In FIG. 5, storage identification information, camera identification information, storage name, and installation position information are registered as storage information. The storage identification information represents identification information for identifying the cylinder cabinet 10 . The camera identification information represents identification information for identifying the cameras 15 provided in the cylinder cabinet 10 . The storage name represents the name of the cylinder cabinet 10 . The installation position information represents position information where the cylinder cabinet 10 is installed. The installation position information may be represented by latitude and longitude.

The tag identification information represents identification information for identifying the electronic tag attached to the gas container B. FIG. By attaching the electronic tag to the gas container B, the position of the gas container B can be managed based on the information of the electronic tag even if the installation location of the gas container B is changed. The cylinder cabinet 10 is equipped with a reader (not shown) for reading information from electronic tags. The carry-in date represents the date when the gas container B was carried into the storage (cylinder cabinet 10). The carry-out date represents the date on which the gas container B was carried out to the storage. Note that not all information is necessarily registered in the management table 323 .

Next, information displayed on the display unit 35 of the management server 30 in response to the user operating the management server 30 and starting the monitoring application 321 will be described. FIG. 6 is a diagram showing an example of a display image IM1 displayed when the monitoring application 321 is activated. The display image IM1 is, for example, a GUI (Graphical User Interface). In the display image IM1 shown in FIG. 6, for example, different information is displayed in each of the regions R1 and R2. A plurality of items for switching the display image to be displayed on the display unit 35 are displayed in the region R1 of the display image IM1. For example, in FIG. 6, items such as a dashboard and a camera are displayed in the area R1. Note that these are only examples, and other items (for example, setting items, maintenance items, etc.) may be displayed in the region R1.

The dashboard item is an item for displaying an image of the dashboard screen in the region R2 of the display unit 35 . In addition, in FIG. 6, an image of the dashboard screen is displayed. The camera item is an item for displaying real-time recorded data of the selected camera 15 on the screen of the display unit 35 . The camera item is selected when the user wants to monitor the state inside the cylinder cabinet 10 in real time. For example, when the user selects a camera item displayed in the area R1 and selects a specific camera 15, the display unit 35 of the management server 30 displays the display image IM2 of FIG.

FIG. 7 is a diagram showing an example of a display image IM2 for monitoring the state inside the cylinder cabinet 10 in real time. The display image IM2 is, for example, a GUI. For example, a display image inf1 is superimposed on the display image IM2 shown in FIG. The display image inf1 is real-time recorded data recorded by the selected camera 15 and provided from the recording server 20 . The user can monitor the state inside the cylinder cabinet 10 in real time by viewing the display image inf1.

Returning to FIG. 6, the description continues. Content based on the information stored in the storage unit 32 of the management server 30 is displayed in the region R2 of the display image IM1. For example, the area R2 displays information indicating the current number of alarms, low remaining capacity information, the number of today's tasks, information on supply facilities, an alert list, a calendar, other status information, a task calendar, and the like. The current number of alarms indicates the number of event information. The number of remaining amount decrease information indicates the number of gas cylinders B whose remaining amount is less than the threshold among the remaining amount information notified from the cylinder cabinet 10 . The number of today's tasks represents the number of tasks registered as scheduled to be performed by the worker on the day. The number of tasks for today is displayed based on the information registered in advance in the task calendar (displayed on the right side of the alert list).

The information about the supply equipment is information about the equipment installed in the high-pressure gas equipment monitoring system 1 . In FIG. 6, a plurality of cylinder cabinets 10 (XX_C/C, X1_C/C, . Although not shown in FIG. 6, the display of each cylinder cabinet 10 may be changed based on the remaining amount information of the cylinder cabinet 10. FIG. For example, the cylinder cabinet 10 with a remaining amount of 100 may be displayed in such a manner that the remaining amount is 100.

Event information notified from the cylinder cabinet 10 is displayed in the alert list. Event information displayed in the alert list may be deleted from the alert list after confirmation by the user is completed. Here, confirmation completion by the user may be the selection of a confirmation completion button (not shown) or the selection once. The alert list displays items such as date and time of occurrence, tag, place, device name, gas name, state level, and video. Information on the date and time when the event occurred is displayed in the item of date and time of occurrence. The tag item displays the identification information of the electronic tag attached to the target gas container B in which the event occurred. If the cause of the event occurrence is other than the gas container B, the information may not be displayed in the tag item.

The location item displays information about the location where the event occurred. The device name item displays the name of the device (equipment) in which the event occurred. The gas name item displays the name of the gas stored in the device in which the event occurred. The status level item displays the content of an event that has occurred (for example, gas leak, ignition detection, erroneous work, etc.). The video item displays information indicating that the recorded data when the event occurred can be checked.

When the user selects the video button in the event information displayed in the alert list, the display image IM3 of FIG. 8 is displayed on the display unit 35 of the management server 30. FIG. FIG. 8 is a diagram showing an example of a display image IM3 for monitoring the state inside the cylinder cabinet 10 when an event occurs. The display image IM3 is, for example, a GUI. For example, a display image inf2 is superimposed on the display image IM3 shown in FIG. The display image inf2 is event recording data related to the event information selected by the user. The user can monitor the state inside the cylinder cabinet 10 at the time of event occurrence by viewing the display image inf2.

In the display image inf2, time information and various buttons are displayed in addition to the event recording data. For example, "20XX/Y1/ZZ" in the display image inf2 represents the time of the event recording data. The display button is a button for displaying recorded data of a specified date and time. The live start button is a button for restarting display of real-time recorded data. When the live start button is selected by the user, the display image IM2 of FIG. 7 is displayed on the display unit 35 of the management server 30. FIG. The display image IM2 displayed when the live start button is selected is real-time recorded data recorded in real time by the camera 15 that recorded the event recorded data.

The stop button is a button for stopping video playback. The frame advance button is a button for playing back recorded data frame by frame. The play button is a button for playing back recorded data. The fast-forward button is a button for fast-forwarding and reproducing recorded data. The 10-second rewind button is a button for displaying recorded data 10 seconds before. The 10-second advance button is a button for displaying recorded data after 10 seconds. In this way, the user can also grasp the state inside the cylinder cabinet 10 before and after the occurrence of the event by operating various buttons.

Returning to FIG. 6, the description continues. Other status information includes, for example, information indicating the status of gas orders. Details of tasks registered in the task calendar are displayed in the task calendar details.

FIG. 9 is a sequence diagram showing the flow of recording data storage processing of the high-pressure gas equipment monitoring system 1 in the embodiment.
The camera 15 of the cylinder cabinet 10 constantly records the inside of the cylinder cabinet 10 (step S101). The camera 15 transmits real-time recorded data obtained by continuous recording to the recording server 20 in real time via the network 40 (step S102). Note that one or more relay devices may be provided between the camera 15 and the recording server 20 .

The communication unit 21 of the recording server 20 receives real-time recording data transmitted from the camera 15 . The recording unit 231 classifies the real-time recorded data received by the communication unit 21 according to the identification information of the camera 15 and stores them in the storage unit 22 (step S103). Each camera 15 of each cylinder cabinet 10 constantly records. The recording unit 231 classifies the real-time recorded data recorded in real time by each camera 15 for each camera 15 in chronological order and stores them in the storage unit 22 .

Assume that the cylinder cabinet 10 detects the occurrence of an event (step S104). For example, assume that a gas leak is detected in the cylinder cabinet 10 . The cylinder cabinet 10 notifies the camera 15 of the time when the occurrence of the event is detected. The camera 15 specifies the recorded data to be time-stamped based on the notified time information, and adds the time stamp to the specified recorded data (step S105). Specifically, the camera 15 identifies the recorded data recorded at the time indicated by the notified time information, and adds a time stamp to the identified recorded data. The time stamp given to the recorded data is information on the time notified from the cylinder cabinet 10 . The camera 15 generates event recorded data including recorded data for a predetermined period before and after the recorded data to which the time stamp is attached, and transmits the generated event recorded data to the recording server 20 via the network 40 ( step S106).

Note that the occurrence of an event may be detected by the camera 15 . In this case, the camera 15 notifies the control device of the cylinder cabinet 10 of the occurrence of the event and the detection time of the occurrence of the event. The camera 15 specifies the recorded data to be time-stamped based on the detection time of the occurrence of the event, and adds the time stamp to the specified recorded data. The camera 15 generates event recorded data including recorded data for a predetermined period before and after the recorded data to which the time stamp is attached, and transmits the generated event recorded data to the recording server 20 via the network 40.例文帳に追加

The communication unit 21 of the recording server 20 receives event recording data transmitted from the camera 15 . The recording unit 231 classifies the event recordings received by the communication unit 21 according to the identification information of the camera 15 and stores them in the storage unit 22 (step S107).

After detecting the occurrence of an event or receiving notification of the occurrence of an event from the camera 15, the cylinder cabinet 10 transmits event information to the management server 30 (step S108). The communication unit 31 of the management server 30 receives event information transmitted from the cylinder cabinet 10 . The acquisition unit 331 stores the event information received by the communication unit 31 in the storage unit 32 as the display information 324 (step S109).

The process described above is the flow of the recording data storage process of the high-pressure gas facility monitoring system 1, but the processes from step S104 to step S109 are not executed while an event is not detected.

FIG. 10 is a sequence diagram showing the flow of recorded data display processing of the management server 30 in the embodiment.
The display control unit 332 activates the monitoring application 321 according to the user's operation (step S201). When the monitoring application 321 is activated, the display control unit 332 causes the display image IM1 (dashboard) to be displayed on the screen of the display unit 35 (step S202). After that, the display control unit 332 causes the display unit 35 to display an image according to the user's operation (step S203). Assume that the user selects the video button of the alert list.

The request unit 333 requests the recording server 20 to provide the event recording data related to the event information corresponding to the video button selected by the user (step S204). Specifically, first, the request unit 333 identifies the camera 15 based on the tag, location, device name, etc. associated with the video button selected by the user. Next, the request unit 333 generates a request signal including the identification information of the specified camera 15 and the time information when the event occurred. The request unit 333 then transmits the generated request signal to the recording server 20 via the communication unit 31 .

The communication unit 21 of the recording server 20 receives the request signal transmitted from the management server 30 . The providing unit 232 acquires the requested event recorded data from the event recorded data 222 based on the identification information of the camera 15 and the time information when the event occurred, which are included in the request signal. Specifically, the providing unit 232 extracts the event recorded data recorded by the camera 15 specified by the identification information of the camera 15 from the event recorded data 222 and the time indicated by the event occurrence time information. is obtained as the requested event recorded data. The provision unit 232 transmits the acquired event recording data to the management server 30 via the communication unit 21 (step S205).

The communication unit 31 of the management server 30 receives event recording data transmitted from the recording server 20 . The display control unit 332 displays the received event recording data on the display unit 35 (step S206).

According to the high-pressure gas facility monitoring system 1 configured as described above, it is possible to shorten the time required to analyze the cause of troubles occurring in facilities that use high-pressure gas. Specifically, in the high-pressure gas facility monitoring system 1, one or more cylinder cabinets 10 for storing the gas container B, a camera 15 for recording the inside of the cylinder cabinet 10, and the inside of the cylinder cabinet 10 recorded by the camera 15 and a management server 30 for displaying the recorded data stored in the recording server 20 according to an input instruction. Thereby, the user can see the recorded video of the state inside the cylinder cabinet 10 . Therefore, when trouble occurs, it is possible to easily grasp what kind of work was done and what state the inside of the cylinder cabinet 10 was in. As a result, confirmation work can be performed in a short time. Therefore, it is possible to shorten the time required to analyze the cause of a trouble occurring in a facility that uses high-pressure gas.

Furthermore, in the high-pressure gas equipment monitoring system 1, the camera 15 gives a time stamp to the recorded data with the occurrence of an event inside the cylinder cabinet 10 as a trigger, and the recorded data for a predetermined period including the time-stamped recorded data. is transmitted to the recording server 20 . The recording server 20 stores event recording data transmitted from the camera 15 . Thereby, it is possible to store the recorded data for a predetermined period including the event occurrence time. Therefore, the user can grasp the state inside the cylinder cabinet 10 before and after the occurrence of the event by viewing the event recording data. Therefore, it is possible to shorten the time required to analyze the cause of a trouble occurring in a facility that uses high-pressure gas.

Modifications of the high-pressure gas facility monitoring system 1 will be described below.
(Modification 1)
When the camera 15 has a moving body detection function, the moving body detection function of the camera 15 in the high-pressure gas facility monitoring system 1 may be used to connect the cylinder cabinet 10 to the cylinder transport cart that transports the gas cylinder B by automatic operation. may be configured to Here, the carriage for transporting the cylinders is composed of a transport vehicle for transporting the gas cylinder B by itself and a loading/unloading robot for automatically loading and unloading the gas cylinder B. As shown in FIG. The transport vehicle is an unmanned transport vehicle called an AGV (Automated Guided Vehicle), and transports the gas container B by automatic operation. The carry-in/carry-out robot is installed on the upper portion of the carrier vehicle, and carries out the carry-out and carry-in of the gas container B automatically. Such a cylinder transport cart can automatically carry out and carry in the gas cylinder B from/to the cylinder cabinet 10 while sliding the gas cylinder B in an upright state. Therefore, when the cylinder transport truck and the cylinder cabinet 10 are not connected, the gas container B cannot be carried out and carried in. As shown in FIG. Therefore, the high-pressure gas equipment monitoring system 1 may be configured to detect whether or not the cylinder transport cart and the cylinder cabinet 10 are connected by using the motion detection function of the camera 15 . When the camera 15 determines that the cylinder transport truck and the cylinder cabinet 10 are not connected, the cylinder cabinet 10 issues an alert or notifies the management server 30 of the alert.

(Modification 2)
When the camera 15 has a moving body detection function, the high-pressure gas equipment monitoring system 1 may be configured to use the moving body detection function of the camera 15 for opening and closing the automatic door of the cylinder cabinet 10 . Conventionally, when a sensor or the like detects that the cylinder transport truck is approaching the cylinder cabinet 10, the cylinder cabinet 10 automatically opens the door and detects that the cylinder transport truck has left the cylinder cabinet 10. At that time, the cylinder cabinet 10 was configured to close the automatic door. In this case, it is conceivable that the automatic door of the unrelated cylinder cabinet 10 may be opened/closed due to erroneous detection of the sensor. Therefore, the high-pressure gas equipment monitoring system 1 may be configured to detect whether or not the cylinder transport truck is positioned in front of the cylinder cabinet 10 by using the moving object detection function of the camera 15 . When it is determined by the camera 15 that the cylinder transport cart is stopped in front of the cylinder cabinet 10, the cylinder cabinet 10 performs control to open the automatic door. On the other hand, when the camera 15 determines that the cylinder transport cart is not stopped in front of the cylinder cabinet 10 while the automatic door of the cylinder cabinet 10 is open, the cylinder cabinet 10 controls the automatic door to close. conduct.

(Modification 3)
When the camera 15 has a moving body detection function, the high-pressure gas facility monitoring system 1 may be configured to perform processing according to user's gestures. It is assumed that user's gestures and processing according to the gestures are stored in the camera 15 in advance. The processing according to the gesture includes, for example, processing to move the cylinder transport cart, processing to cancel the authentication of the tablet terminal provided in the cylinder cabinet 10, processing to open or close the automatic door of the cylinder cabinet 10, and the like. Note that the processing according to the gesture is not limited to these. When the camera 15 detects a predetermined sign for executing the processing of moving the cylinder transport cart, the camera 15 notifies the management server 30 of processing information corresponding to the gesture via the cylinder cabinet 10 . In accordance with the notified information, the management server 30 transmits a movement instruction to the cylinder transport cart and moves the cylinder transport cart to the position of the user (for example, the position of the cylinder cabinet 10 equipped with the camera 15 that detected the predetermined sign). ).

(Modification 4)
The high-pressure gas facility monitoring system 1 may be configured so that a user located at a remote location can give work instructions while viewing recorded data recorded by the camera 15 . In this case, the recording server 20 provides the requested recorded data in real time to the communication device operated by the user who requests the recorded data. As a result, even a user in a remote location can view a desired image inside the cylinder cabinet 10 in real time. A user at a remote location can give a work instruction to a worker working on-site by using a communication device or other means.

(Modification 5)
When the camera 15 has a sound collection function and a voice output function, the high-pressure gas equipment monitoring system 1 is configured to perform operations by voice recognition, read out maintenance procedures and give an answerback, or issue an alarm when an abnormal sound occurs. good too. When the camera 15 has a sound collection function (microphone), sound can be collected within the cylinder cabinet 10 . The camera 15 may detect whether or not there is an abnormal sound based on the collected sound, and issue an alert when the abnormal sound is generated.

(Modification 6)
In the above-described embodiment, the event recording data is saved in accordance with the occurrence of an event in the cylinder cabinet 10. However, the event recording data may be saved in response to the occurrence of an event in another facility. may be configured to For example, the high-pressure gas equipment monitoring system 1 may be configured to store event recording data in response to the occurrence of an event in a container such as a cylinder stocker used to store the gas container B, or to store the event recording data. The event recording data may be saved according to the occurrence of an event in another facility installed in the supply facility.

(Modification 7)
In the above-described embodiment, the configuration is shown in which the camera 15 adds a time stamp to the recorded data and transmits it to the recording server 20, but the control device of the cylinder cabinet 10 adds a time stamp to the recorded data. Alternatively, a server provided on the cloud may add a time stamp to the recorded data. In this case, the control device of the cylinder cabinet 10 or the server provided on the cloud is provided with a giving unit that gives a time stamp.

Although the embodiment of the present invention has been described in detail with reference to the drawings, the specific configuration is not limited to this embodiment, and design and the like are included within the scope of the gist of the present invention.

DESCRIPTION OF SYMBOLS 10... Cylinder cabinet, 12... Control box, 15... Camera, 20... Recording server, 30... Management server, 21... Communication part, 22... Storage part, 23... Control part, 221... Recording data, 231... Recording part, 232 ... providing unit, 31... communication unit, 32... storage unit, 33... control unit, 34... operation unit, 35... display unit, 331... acquisition unit, 332... display control unit, 333... request unit, 321... monitoring application, 322...Container table, 323...Management table, 323...Management table, 324...Display information

Claims (9)

one or more storages for storing gas containers filled with high-pressure gas;
A camera that records the inside of the storage,
a recording server that stores recorded data inside the repository recorded by the camera;
an assigning unit that assigns a time stamp to recorded data triggered by the occurrence of an event inside the one or more storages;
a display device for displaying recorded data stored in the recording server according to an input instruction;
with
the camera transmits, as event recorded data, recorded data for a predetermined period including recorded data to which the time stamp is added by the adding unit to the recording server;
The high-pressure gas facility monitoring system , wherein the recording server stores the event recording data transmitted from the camera as the recording data . The one or more storage notifies event information regarding event occurrence to the display device,
The display device displays the notified event information, and displays the event recording data corresponding to the event indicated by the selected event information.
The high-pressure gas facility monitoring system according to claim 1 . When the display device requests the recording server for the event recording data corresponding to the event indicated by the selected event information, the display device requests at least the identification information of the camera that recorded the event recording data and the event occurrence information. sending a request signal including time information to the recording server;
The recording server selects the event recording data recorded by the camera specified by the identification information of the camera included in the request signal from among the event recording data stored, and the time information when the event occurred. Providing the display device with event recording data whose indicated time matches the time indicated by the attached time stamp;
The high-pressure gas equipment monitoring system according to claim 2 . The camera has a moving body detection function, and detects the presence or absence of an abnormality by the moving body detection function in the work being performed inside the storage,
The one or more storages issue an alert when an abnormality is detected by the camera,
The high-pressure gas equipment monitoring system according to any one of claims 1 to 3 . The camera has a function of displaying a temperature distribution on an image by synthesizing information on the heat inside the storage, which is obtained by a heat sensor that detects heat, with the captured image, or a function of detecting heat. and detect the presence or absence of ignition inside the storage based on the results obtained by any of the functions,
The one or more storages issue an alert when ignition is detected by the camera;
The high-pressure gas equipment monitoring system according to any one of claims 1 to 3 . Further comprising a cylinder transport trolley for transporting the gas container,
The one or more storages are cylinder cabinets,
The camera has a moving object detection function, and detects whether or not the cylinder transport cart and the cylinder cabinet are connected by the moving object detection function,
The cylinder cabinet issues an alert when the camera determines that the cylinder transport cart and the cylinder cabinet are not connected.
The high-pressure gas equipment monitoring system according to any one of claims 1 to 3 . Further comprising a cylinder transport trolley for transporting the gas container,
The one or more storages are cylinder cabinets,
The camera has a moving object detection function, and detects whether or not the cylinder transport cart is positioned in front of the cylinder cabinet by the moving object detection function,
The cylinder cabinet opens the door when it is determined that the cylinder transport cart is positioned in front of the cylinder cabinet.
The high-pressure gas equipment monitoring system according to any one of claims 1 to 3 . The camera has a motion detection function, and detects a user's movement with the motion detection function,
The one or more storages execute processing according to the detected movement of the user,
The high-pressure gas equipment monitoring system according to any one of claims 1 to 3 . Recording the inside of one or more storage containers containing gas containers filled with high pressure gas,
Save the recorded data inside the recorded storage,
Giving a time stamp to the recorded data with the occurrence of an event inside the one or more storages as a trigger,
transmitting recorded data for a predetermined period including recorded data with time stamps as event recorded data;
storing the transmitted event recording data as the recording data;
display stored recorded data according to input instructions;
High pressure gas equipment monitoring method.

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