JP6278228B2 - NAVIGATION DEVICE AND NAVIGATION METHOD - Google Patents

Description

  The present invention relates to a technique for dealing with a gas leak generated in a plant.

  Conventionally, a technique corresponding to a case where smoke or gas is generated has been proposed. For example, Patent Literature 1 describes, based on a series of continuous video images of a monitoring area, when the analysis unit can identify an area where smoke may be growing or moving in the monitoring area. A warning means discloses a system for issuing a warning. Further, for example, Patent Document 2 discloses a system in which guidance means displays an evacuation guidance instruction when an abnormality in gas concentration occurs in an underground storage facility.

  For example, when a gas leak occurs in a plant that performs predetermined processing on gas, such as a plant that regasifies liquefied natural gas, it is necessary to urge workers to stop the gas leak at the gas leak location. A plant that performs a predetermined treatment on gas is relatively large, and a passage network is formed in the plant. A passage with a high gas concentration is dangerous due to gas leakage. If it takes time for the worker to arrive at the gas leak point, the work for stopping the gas leak is delayed by that much.

US Pat. No. 7,769,204 JP 2011-134214 A

  An object of the present invention is to provide a navigation device and a navigation method capable of safely and quickly navigating a worker to a gas leak point.

  A navigation device according to a first aspect of the present invention that achieves the above object includes a first storage unit, a first acquisition unit, a second acquisition unit, a calculation unit, and an output unit. The first storage unit stores passage network data indicating a passage network provided in the plant in advance. A 1st acquisition part acquires the 1st position information which shows the position of the gas leak location in which the gas leak has generate | occur | produced in the said plant. A 2nd acquisition part acquires the 2nd position information which shows the position of the range of the gas cloud which has arisen by the gas leak. The calculation unit uses the passage network using the passage network data, the first position information, the second position information, and third position information indicating a predetermined position in the plant. A shortest path that can reach the position of the gas leakage point from the predetermined position and does not overlap the range of the gas cloud is calculated. The output unit outputs image data of an image indicating the shortest path.

  The above and other objects, features and advantages of the present invention will become apparent from the following detailed description and the accompanying drawings.

It is a block diagram which shows the structure of the navigation system which concerns on this embodiment. It is a block diagram which shows the hardware constitutions of the control processing part shown to FIG. 1A. It is a mimetic diagram showing an example of a channel network provided in a plant where a navigation system shown in Drawing 1A is arranged. It is an image figure which shows one of the images which comprise the image | video of the allocation area | region image | photographed with the visible camera with which a certain monitoring apparatus is equipped. It is explanatory drawing for demonstrating the heat distribution image of the allocation area | region produced | generated with an infrared camera. It is a schematic diagram which shows an example of the heat distribution image of the allocation area | region containing a gas cloud area | region image produced | generated with an infrared camera. It is explanatory drawing for demonstrating the calculation method of a density thickness product. It is explanatory drawing explaining an example of the specific method of a gas leak location. It is a flowchart explaining operation | movement of the navigation system which concerns on this embodiment. It is a flowchart following the flowchart shown in FIG. It is a schematic diagram which shows the 1st example of the image which shows the shortest path | route to a gas leak location. It is a schematic diagram which shows the 2nd example of the image which shows the shortest path | route to a gas leak location. It is a schematic diagram which shows the 3rd example of the image which shows the shortest path | route to a gas leak location. It is a schematic diagram which shows the example which cannot calculate the shortest path | route to a gas leak location. It is a schematic diagram which shows an example of the image which shows the shortest path | route to an evacuation location. It is an image figure which shows the modification containing the range of a gas cloud, and the image containing the shortest path | route to a gas leak location.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. In each figure, the structure which attached | subjected the same code | symbol shows that it is the same structure, The description is abbreviate | omitted about the content which has already demonstrated the structure.

  FIG. 1A is a block diagram showing a configuration of a navigation system 1000 according to the present embodiment. FIG. 2 is a schematic diagram showing an example of a passage network 83 provided in a plant in which the navigation system 1000 is arranged.

  Referring to FIG. 2, plant site 80 is surrounded by wall 81. The wall 81 is provided with one or a plurality of doorways. In this embodiment, two entrances 82a and 82b are provided. The plant can be entered and exited via the entrances 82a and 82b. The plant is, for example, a plant that liquefies natural gas, a plant that regasifies liquefied natural gas, or a plant that generates electricity by burning natural gas. The site 80 includes a passage network 83, a central monitoring building 84, A waiting place 85, although not shown, is provided with a gas processing facility, a gas tank, a gas transport pipe, and the like. The central monitoring building 84, the waiting station 85, the gas processing facility, the gas tank, the gas transport pipe, and the like may be represented by symbols, their actual shapes may be represented by planes, or their actual shapes. May be expressed in three dimensions.

  The passage network 83 is formed by a large number of passages 86 in the site 80. A black circle denoted by reference numeral 87 is a branch point of the passage 86.

  The central monitoring building 84 is a facility that manages the entire plant, and this management includes a response when a gas leak occurs in the site 80. The standby station 85 is a facility where a plant worker waits, and when a gas leak occurs in the plant, the worker heads from the standby station 85 to the gas leak point in order to stop the gas leak.

  Referring to FIGS. 1A and 2, a navigation system 1000 includes a navigation device 1, n monitoring devices 2-1 to 2 -n, a desktop personal computer 3, and a mobile terminal 4.

  The n monitoring devices 2-1 to 2-n (hereinafter referred to as the monitoring device 2 when these monitoring devices are not distinguished) are arranged in the site 80. A predetermined area (hereinafter referred to as an allocation area) in the site 80 is allocated to each of the n monitoring devices 2. Each of the n monitoring devices 2 monitors a gas leak in the allocated area.

  The monitoring device 2 includes a visible camera 21, an infrared camera 22, and a distance measuring sensor 23.

  The visible camera 21 is connected to the navigation device 1 and acquires the video data of the allocation area according to the control of the navigation device 1. The visible camera 21 continuously captures the allocated area for 24 hours, and outputs the captured video data to the navigation device 1. FIG. 3 is an image diagram showing one of the images constituting the video of the allocated area taken by the visible camera 21 provided in a certain monitoring device 2. In this image Im1, a gas transport pipe, a gas tank, and the like are shown.

  The visible camera 21 is, for example, an imaging optical system that forms a visible optical image of the allocation area on a predetermined imaging plane, and is arranged with the light receiving surface coincident with the imaging plane. An image sensor for converting into a typical signal, an image processing unit for generating image data by performing image processing on the output of the image sensor, and the like.

  The infrared camera 22 is connected to the navigation apparatus 1 and images infrared rays from the allocation area under the control of the navigation apparatus 1 to generate a heat distribution image of the allocation area. The infrared camera 22 is, for example, an imaging optical system that forms an infrared optical image of an allocation area on a predetermined imaging surface, and is arranged with a light-receiving surface coincident with the imaging surface. An infrared image sensor for converting into a typical signal, an infrared image processing unit for generating heat distribution image data by performing image processing on the output of the infrared image sensor, and the like. The infrared camera 22 generates a heat distribution image (heat distribution image data) of the assigned region continuously for 24 hours, and outputs the generated heat distribution image data to the navigation device 1.

  The distance measuring sensor 23 is connected to the navigation device 1 and measures the distance from the infrared camera 22 to the gas cloud (leakage gas cloud) under the control of the navigation device 1. A gas cloud is an object formed in a space by gas (leakage gas) leaked from an allocation area. The distance measuring sensor 23 is a sensor that measures a distance, such as an optical type, an ultrasonic type, and a laser beam type.

  The navigation apparatus 1 is disposed in the central monitoring building 84 and includes a control processing unit 10, interface units 11 and 12, a display unit 13, and an input unit 14.

  The interface unit 11 is connected to the control processing unit 10 and is an interface for communicating between the control processing unit 10 and the n monitoring devices 2 according to the control of the control processing unit 10. The interface unit 11 and the n monitoring devices 2 may be directly connected or may be connected via a LAN installed in the site 80. The interface unit 11 is, for example, a communication card for wired communication or wireless communication.

  The interface unit 12 is connected to the control processing unit 10 and communicates between the control processing unit 10 and the desktop personal computer 3 and between the control processing unit 10 and the mobile terminal 4 under the control of the control processing unit 10. It is an interface for. The interface unit 12 is, for example, a communication card for wired communication or wireless communication. The desktop personal computer 3 is arranged in the waiting place 85. The mobile terminal 4 is carried by a worker heading from the waiting place 85 to the gas leaking place.

  The display unit 13 is connected to the control processing unit 10, an input screen for inputting various commands to the control processing unit 10, an image of the allocation area captured by the visible camera 21 (for example, the image Im <b> 1 shown in FIG. 3), In addition, an image or the like indicating the shortest path described later is displayed. The display unit 13 is, for example, an LCD.

  The input unit 14 is connected to the control processing unit 10. For example, the input unit 14 inputs various commands to the control processing unit 10 or inputs an instruction to switch an image in the allocation area. The input of the switching instruction is, for example, an image of the allocation area captured by the visible camera 21 when an instruction to display an image of the allocation area captured by the visible camera 21 of the monitoring device 2-1 is input. Is displayed on the display unit 13. The input unit 14 is, for example, a keyboard and a mouse.

  The control processing unit 10 is necessary for operations of the CPU (Central Processing Unit), RAM (Random Access Memory), ROM (Read Only Memory), HDD (Hard Disk Drive) and the like, and the operation of the navigation device 1. It is realized by various software such as various programs and data. The control processing unit 10 includes, as functional blocks, a display control unit 100, a passage network data storage unit 101, a video data storage unit 102, a gas cloud processing unit 103, a gas concentration calculation unit 104, a gas leak location specifying unit 105, a standby location. The storage unit 106, the mobile terminal position acquisition unit 107, the evacuation position storage unit 108, the gas leak location route calculation unit 109, the gas cloud safety determination unit 110, the gas concentration safety determination unit 111, the evacuation route calculation unit 112, and the arrival determination unit 113. Prepare.

  The display control unit 100 controls the display unit 13 to display the above-described input screen, allocation area image, image indicating the shortest path, and the like.

  The passage network data storage unit 101 (an example of a first storage unit) stores passage network data indicating the passage network 83 in advance. Specifically, the path network data includes position information indicating the position of each branch point 87, information indicating the distance of each path 86, and information specifying the branch points 87 positioned at both ends of each path 86 (for example, both ends of the path 86a). Information indicating that the branch points 87a and 87b are located), position information indicating the position of each facility provided on the site 80 (for example, position information of the waiting place 85), and the like. The position information means two-dimensional position information.

  The video data storage unit 102 stores the video data of the n allocation areas transmitted from the visible cameras 21 of the n monitoring devices 2 for a predetermined period.

  The gas cloud processing unit 103 functionally includes a gas cloud image region extraction unit 1030 and a concentration / thickness product calculation unit 1031. The gas cloud image region extraction unit 1030 extracts a gas cloud image region in the gas cloud formed by the gas leaking from the allocation region based on the heat distribution image of the target region generated by the infrared camera 22. The gas cloud processing unit 103 determines that a gas leak has occurred when the gas cloud image region can be extracted. The concentration / thickness product calculation unit 1031 obtains the concentration / thickness product of the leaked gas cloud based on the gas cloud image region extracted by the gas cloud image region extraction unit 1030 by using known conventional means. Preferably, the concentration / thickness product calculation unit 1031 uses the gas absolute temperature of the gas cloud and the background absolute temperature of the background of the gas cloud based on the gas cloud image region extracted by the gas cloud image region extraction unit 1030 to generate the gas. Find the cloud density thickness product.

  Hereinafter, the operation of the gas cloud processing unit 103 will be described. FIG. 4 is a diagram for explaining a heat distribution image of the allocation area generated by the infrared camera 22. FIG. 5 is a diagram illustrating an example of the heat distribution image of the allocation region including the gas cloud region image generated by the infrared camera 22. FIG. 6 is a diagram for explaining a method of calculating the concentration / thickness product.

  The gas cloud processing unit 103 acquires a heat distribution image transmitted from the infrared cameras 22 of the n monitoring devices 2, and the gas cloud image region extraction unit 1030 extracts a gas cloud image region from the heat distribution image. (Process 1). More specifically, the infrared camera 22 images infrared rays (background radiation infrared rays) radiated from individual objects (background objects) existing in the allocation area. Here, as shown in FIG. 4, when a gas cloud exists between the infrared camera 22 and the background object, the background radiation infrared rays reach the infrared camera 22 through the gas cloud. The gas cloud absorbs a part of the background radiation infrared rays and radiates infrared rays according to the temperature of the gas cloud itself. The amount of absorption of the background radiation infrared ray follows the concentration of the gas cloud and follows the thickness of the gas cloud. For example, the absorption amount of a gas cloud having a low concentration and a large thickness is equal to the absorption amount of a gas cloud having a high concentration and a thin thickness when the concentration-thickness products are equal. For this reason, the image of the allocation region imaged and generated by the infrared camera 22 becomes a heat distribution image having a temperature distribution depending on the presence or absence of the gas cloud, and in this heat distribution image, the luminance value of the image part through the gas cloud is It is different from the luminance value of the image portion not passing through the gas cloud. Therefore, the gas cloud processing unit 103 can extract a gas cloud image region of the gas cloud by extracting a pixel region having a luminance value equal to or lower than a predetermined determination threshold th1 set in advance from the heat distribution image.

  When the gas cloud image region extraction unit 1030 can extract the gas cloud image region from the heat distribution image, the gas cloud processing unit 103 includes the infrared camera 22 that generates the heat distribution image from which the gas cloud image region can be extracted. It is determined that a gas leak has occurred in the allocation area allocated to the device 2 (for example, the monitoring device 2-1). The control processing unit 10 causes the distance measuring sensor 23 provided in the monitoring device 2 (monitoring device 2-1) to measure the distance from the infrared camera 22 to the gas cloud, and acquires the measured distance (processing 2).

  Next, the concentration / thickness product calculation unit 1031 obtains the concentration / thickness product of the gas cloud based on the extracted gas cloud image region (processing 3). More specifically, for example, as shown in FIG. 5, the concentration-thickness product calculation unit 1031 is based on the gas cloud image region extracted by the gas cloud image region extraction unit 1030 and the gas absolute temperature of the gas cloud and the background of the gas cloud. The concentration-thickness product (ppm · m) of the gas cloud is obtained by using the background absolute temperature. The background absolute temperature is determined by a known conventional means, for example, the luminance value of the pixel of the infrared camera 22 (for example, the maximum luminance value in a heat distribution image that can be estimated not to pass through the gas cloud), the imaging optical system of the infrared camera 22 It is obtained from the infrared brightness calculated from the lens F value and the infrared transmittance of the atmosphere. The absolute gas temperature is estimated by known conventional means, for example, by estimating the temperature drop due to adiabatic expansion and taking into account the temperature change due to subsequent thermal diffusion. Alternatively, the concentration-thickness product calculation unit 1031 can be obtained from two different background temperatures in the gas cloud having the same concentration as shown in FIG.

  The gas cloud processing unit 103 stores in advance data in which the two-dimensional position of each pixel constituting the heat distribution image transmitted from the infrared camera 22 is associated with the two-dimensional position of each part of the allocation region. . The gas cloud processing unit 103 calculates the position (two-dimensional position) of the range of the gas cloud in the allocation area using this data. Therefore, the gas cloud processing unit 103 has a function of a second acquisition unit. A 2nd acquisition part acquires the 2nd position information which shows the position of the range of the gas cloud which has arisen by gas leak. In the present embodiment, the navigation device 1 calculates the position of the gas cloud range. However, another device calculates the position of the gas cloud range. You may acquire the 2nd positional information which shows the position of a range.

  The gas concentration calculation unit 104 calculates the concentration of the gas cloud using the concentration thickness product of the gas cloud obtained in the process 3. More specifically, the gas concentration calculation unit 104 calculates the horizontal width of the gas cloud using the horizontal width of the gas cloud image region extracted in the process 1 and the distance from the infrared camera 22 acquired in the process 2 to the gas cloud. . The gas concentration calculation unit 104 uses the calculated lateral width as the thickness of the gas cloud (in other words, the size in the depth direction of the gas cloud), and uses the concentration thickness product of the gas cloud obtained by the concentration thickness product calculation unit 1031 as the thickness of the gas cloud. And the concentration of the gas cloud is obtained as a result of the division ((gas cloud concentration [ppm]) = (concentration thickness product [ppm · m]) / (thickness [m])).

  Therefore, the gas concentration calculation unit 104 has a function of a third acquisition unit. The third acquisition unit acquires concentration information indicating the gas concentration of the gas cloud. In the present embodiment, the gas concentration of the gas cloud is calculated by the navigation device 1, but another device calculates the gas concentration of the gas cloud, and the navigation device 1 determines the gas concentration of the gas cloud from the device. Concentration information indicating the above may be acquired.

  When the gas cloud processing unit 103 determines that a gas leak has occurred as described above, the gas leak point specifying unit 105 specifies a gas leak point. There are various specific methods. Here, an example of the specific method will be described. FIG. 7 is an explanatory diagram for explaining an example of a method of specifying a gas leak location. The gas leak location specifying unit 105 includes the same monitoring device 2 (monitoring device 2-1) as the monitoring device 2 (for example, the monitoring device 2-1) including the infrared camera 22 that has generated the heat distribution image from which the gas cloud image region has been extracted. The location where the gas leak has occurred is specified using the video data taken by the visible camera 21 provided in ().

  More specifically, the gas leak location specifying unit 105 acquires, from the video data storage unit 102, data (hereinafter, a plurality of time-series images) from the latest video to a video of a predetermined time before the video data. . The gas leak location specifying unit 105 performs reverse reproduction going back to the past from the latest image in the plurality of time-series images, and for each of the plurality of time-series images, the first image and the first imaging time of the first image. Based on the second image at the second imaging time in the past, the movement trajectory of the leaked gas for the first image is obtained (processing 4).

  For example, the first and second images are two images that are adjacent to each other in chronological order. That is, the first and second images are a frame that is temporally one frame earlier than the frame. This selection method of the first and second images is effective when the gas leak point 88 for the allocation region is detected based on a plurality of time-series images taken in a relatively short time.

  For example, the first and second images are two images that are adjacent to each other with a predetermined time interval in time series order. That is, the first and second images are frames that are temporally previous through the frame and one or more frames from the frame. Accordingly, the first and second images are selected by skipping one or more frames. This selection method of the first and second images is effective in detecting the gas leaking point 88 based on a plurality of time-series images for the allocated area captured for a relatively long time.

  More specifically, in the present embodiment, for example, the gas leakage point specifying unit 105 for each of the pixels of the first image, the optical of the pixel between the frame and the frame immediately before the frame. The flow is obtained as the movement locus of the leaked gas. And the gas leak location specific | specification part 105 performs the process which calculates | requires such a movement locus | trajectory of all the pixels for each of several time-sequential frames in order from the newest flame | frame to the past in order.

  Next, the gas leak location specifying unit 105 stores each movement locus obtained in the process 4 (process 5). For example, the starting pixel position, length and direction in the movement locus are stored. Further, for example, the starting pixel position and the ending pixel position in the movement locus are stored. In this case, since the time interval between the frame and the frame immediately before the frame is determined according to the frame rate (because it is given), the movement locus is a velocity vector, The speed of the moving track can also be calculated.

  Next, the gas leakage location specifying unit 105 obtains a plurality of movement locus sequences in which a plurality of movement loci are arranged in time series starting from a plurality of different locations in the leaking gas, and the obtained plurality of movement loci. It is determined whether or not the end point of the column is included within a predetermined range (processing 6). More specifically, for example, as shown in FIG. 7, the gas leak location specifying unit 105 starts from the movement trajectory obtained from the latest frame among a plurality of time-series frames, and starts from the latest frame. The movement trajectories obtained in each of the frames are arranged in time series, thereby obtaining a plurality of movement trajectory strings, and determining whether or not the end points of the obtained plural movement trajectory strings are included within a predetermined range. . The predetermined range is appropriately set according to the detection accuracy of the gas leak location, etc., and in the case of high accuracy, it is set to a relatively small area (narrow area) quadrangle (such as a square) and low accuracy. In this case, a relatively large area (wide area) quadrangle (for example, a square) is set.

  As a result of this determination, when it is included in the predetermined range (FIG. 7), the gas leak location specifying unit 105 specifies the predetermined range as the gas leak location.

  The gas leak location specifying unit 105 has a function of a first acquisition unit. A 1st acquisition part acquires the 1st positional infomation which shows the position of the gas leak location in which the gas leak has generate | occur | produced in the plant. In the present embodiment, the position of the gas leak point is calculated by the navigation device 1, but another device calculates the position of the gas leak point, and the navigation device 1 determines the position of the gas leak point from the device. You may acquire the 1st position information which shows.

  The standby location storage unit 106 stores location information indicating the location of the standby location 85 in advance. This position information is an example of third position information indicating a predetermined position in the plant.

  The mobile terminal position acquisition unit 107 (fourth acquisition unit) communicates with the mobile terminal 4 using the interface unit 12 to acquire and update the current position of the mobile terminal 4 at a predetermined interval. The current position of the mobile terminal 4 is specified using, for example, GPS. The current position of the mobile terminal 4 (that is, the current position of the worker carrying the mobile terminal 4) is another example of the third position information.

  The evacuation position storage unit 108 (second storage unit) stores in advance position information (fourth position information) indicating the position of the place where the worker evacuates when a gas leak occurs. In the present embodiment, position information indicating the positions of the plant entrances 82 a and 82 b is stored in the evacuation position storage unit 108.

  The gas leakage point route calculation unit 109 (first calculation unit) includes passage network data, gas leakage point position information (first position information), and third position information (for example, position information of the waiting place 85). ) Is used to calculate the first shortest path that is the shortest path that can reach the position of the gas leak location from a predetermined position (for example, the position of the standby station 85) using the passage network 83.

  The first shortest path can be calculated using a known shortest path calculation method. For example, the first shortest path can be calculated by the Dijkstra method using the path network data indicating the path network 83 shown in FIG. The same applies to the second shortest path and the third shortest path described later.

  The gas cloud safety determination unit 110 (first determination unit) determines whether or not the first shortest path overlaps the range of the gas cloud indicated by the second position information described above. The first shortest path and the range of the gas cloud are both shown in two dimensions, so that if the gas cloud is in contact with the first shortest path, if the gas cloud is above the first shortest path, Even in this case, the first shortest path overlaps the range of the gas cloud. The same applies to the second shortest path and the third shortest path described later.

  When it is determined that the first shortest path described above overlaps the range of the gas cloud, the gas concentration safety determination unit 111 (second determination unit) determines the gas of the gas cloud calculated by the gas concentration calculation unit 104. It is determined whether the concentration is equal to or lower than a predetermined dangerous concentration. The dangerous concentration is, for example, a concentration that may cause a gas explosion.

  When the gas leakage point path calculation unit 109 (first calculation unit) described above determines that the gas concentration exceeds the dangerous concentration, the gas leakage path calculation unit 109 excludes a passage that overlaps the range of the gas cloud in the passage network 83. Using the passage network 83 using the passage network data, the gas leak location information (first location information), and the third location information (for example, location information of the waiting place 85). A second shortest path, which is the shortest path that can reach the position of the gas leak point (for example, the position of the standby station 85), is calculated.

  The evacuation route calculation unit 112 (second calculation unit), when the second shortest route cannot be calculated, the passage network data excluding the passage overlapping the gas cloud in the passage network 83, the third position Using the information (for example, the position information of the waiting place 85) and the position information (fourth position information) indicating the position of the evacuation place, a predetermined position (for example, the waiting place 85) using the passage network 83. The third shortest route that is the shortest route that can reach the position of the evacuation point (entrances 82a and 82b) is calculated.

  The arrival determination unit 113 (third determination unit) uses the position information (first position information) of the gas leak location and the position information (updated third position information) of the current position of the mobile terminal 4. Thus, it is determined whether or not the worker carrying the mobile terminal 4 has reached the position of the gas leak point.

  When displaying an image indicating the first shortest path, an image indicating the second shortest path, and an image indicating the third shortest path on the display of the desktop personal computer 3 and the display of the mobile terminal 4, the control processing unit 10 The interface unit 12 functions as an output unit. When these images are displayed on the display unit 13 of the navigation device 1, the control processing unit 10 functions as an output unit. As will be described later, the output unit outputs image data of an image indicating the first shortest path, image data of an image indicating the second shortest path, and image data of an image indicating the third shortest path. .

  FIG. 1B is a block diagram illustrating a hardware configuration of the control processing unit 10. The control processing unit 10 includes a CPU 10a, a RAM 10b, a ROM 10c, an HDD 10d, and a bus 10e for connecting them. The HDD 10d (or the ROM 10c instead of the HDD 10d) includes a display control unit 100, a gas cloud processing unit 103, a gas concentration calculation unit 104, a gas leak location specifying unit 105, a mobile terminal position acquisition unit 107, a gas leak shown in FIG. The location route calculation unit 109, the gas cloud safety determination unit 110, the gas concentration safety determination unit 111, the evacuation route calculation unit 112, and the arrival determination unit 113 store programs for realizing these functional blocks, respectively. . The CPU 10a reads these programs from the HDD 10d, expands them in the RAM 10b, and executes the expanded programs to realize these functional blocks. The flowcharts of these programs executed by the CPU 10a are shown in FIGS. 8 and 9, which will be described later. The aisle network data storage unit 101, the video data storage unit 102, the standby location storage unit 106, and the evacuation location storage unit 108 are realized by the HDD 10d (the ROM 10c may be used instead of the HDD 10d).

  The operation of the navigation system 1000 according to this embodiment will be described. 8 and 9 are flowcharts for explaining this operation. Referring to FIGS. 1A and 8, it is assumed that the gas cloud processing unit 103 detects a gas leak in an allocation region allocated to the monitoring device 2-1 among the n monitoring devices 2.

  The gas cloud processing unit 103 (second acquisition unit) is a range of a gas cloud generated by gas leaked from a gas leak point (not specified at the present time) in the allocation region allocated to the monitoring device 2-1. The position of 89 (for example, the gas cloud range 89 shown in FIG. 10) is specified (step S1).

  The gas leak location specifying unit 105 (first acquisition unit) specifies the position of the gas leak location 88 in the allocation area assigned to the monitoring device 2-1 (step S2).

  The gas leak point route calculation unit 109 (first calculation unit) is configured to store the passage network data stored in the passage network data storage unit 101 (first storage unit) and the position of the gas leak point 88 identified in step S2. Using the information (first position information) and the position information (third position information) of the waiting place 85 stored in the waiting place position storage unit 106, the gas leaking point 88 is detected from the position of the waiting place 85. The shortest path to the position (first shortest path) is calculated (step S3).

  The gas cloud safety determination unit 110 (first determination unit) uses the position information of the gas cloud range 89 specified in step S1 and the shortest path (first shortest path) calculated in step S3. Then, it is determined whether or not the shortest path (first shortest path) overlaps the gas cloud range 89 (step S4).

  When the gas cloud safety determination unit 110 determines that the shortest path does not overlap with the gas cloud range 89 (No in step S4), the gas leak location path calculation unit 109 performs step S3 as shown in FIG. Image data of the image Im2 indicating the calculated shortest path 91 is generated. In the image Im2, a gas leak point 88, a gas cloud range 89, and a shortest path 91 are added to the passage network 83 shown in FIG. The gas cloud range 89 does not overlap the shortest path 91.

  An image Im2 indicating the shortest path 91 is displayed (step S5). That is, the control processing unit 10 outputs the image data of the image Im2 to the display control unit 100, and the display control unit 100 causes the display unit 13 to display the image Im2 indicated by the image data. Further, the control processing unit 10 controls the interface unit 12 to output the image data of the image Im <b> 2 to the desktop personal computer 3 and the mobile terminal 4. As a result, the image Im2 is displayed on the display of the desktop personal computer 3 arranged in the standby station 85, and the image Im2 is displayed on the display of the mobile terminal 4 carried by the worker in the standby station 85. Thus, the control processing unit 10 and the combination of the control processing unit 10 and the interface unit 12 function as an output unit.

  When the gas cloud safety determination unit 110 determines that the shortest path overlaps the gas cloud range 89 (Yes in step S4), that is, the gas cloud range 89 determines that the gas cloud range 89 extends to the shortest path. If yes, go to Step S10.

  The gas concentration calculation unit 104 (third acquisition unit) calculates the gas cloud concentration, that is, the gas concentration in the gas cloud range 89 (step S10).

  The gas concentration safety determination unit 111 (second determination unit) determines whether or not the gas concentration calculated in step S10 is equal to or less than a dangerous concentration that may cause a gas explosion (step S11).

  When the gas concentration safety determination unit 111 determines that the gas concentration is equal to or lower than the dangerous concentration (Yes in step S11), the gas leak location path calculation unit 109 uses the shortest path 91 calculated in step S3 as shown in FIG. Image data of the indicated image Im3 is generated. The image Im3 is different from the image Im2 shown in FIG. 10 in that the gas cloud range 89 extends to the shortest path 91.

  An image Im3 indicating the shortest path 91 is displayed (step S12). That is, the control processing unit 10 outputs the image data of the image Im3 to the display control unit 100, and the display control unit 100 causes the display unit 13 to display the image Im3 indicated by the image data. In addition, the control processing unit 10 controls the interface unit 12 to output the image data of the image Im3 to the desktop personal computer 3 and the mobile terminal 4. As a result, the image Im3 is displayed on the display of the desktop personal computer 3 arranged in the standby station 85, and the image Im3 is displayed on the display of the mobile terminal 4 carried by the worker in the standby station 85.

  When the gas concentration safety determination unit 111 determines that the gas concentration exceeds the dangerous concentration (No in step S11), referring to FIG. It is determined whether or not there is a non-overlapping shortest path (second shortest path) (step S13). More specifically, referring to FIG. 11, the gas leak location route calculation unit 109 includes a passage 86 a that overlaps the gas cloud range 89 from the passage network data stored in the passage network data storage unit 101, and It is determined whether the shortest path can be calculated by excluding the branch points 87a and 87b at both ends of the passage 86a.

  When the gas leak location path calculation unit 109 is able to calculate the shortest route that does not overlap the gas cloud range 89 (Yes in step S13), the gas leak location path calculation unit 109 performs step S13 as shown in FIG. The image data of the image Im4 indicating the shortest path 92 in which the gas cloud range 89 does not overlap is calculated. Image Im4 differs from image Im3 shown in FIG. 11 in that shortest path 91 is replaced with shortest path 92.

  An image Im4 indicating the shortest path 92 is displayed (step S14). That is, the control processing unit 10 outputs the image data of the image Im4 to the display control unit 100, and the display control unit 100 causes the display unit 13 to display the image Im4 indicated by the image data. In addition, the control processing unit 10 controls the interface unit 12 to output the image data of the image Im4 to the desktop personal computer 3 and the mobile terminal 4. As a result, the image Im4 is displayed on the display of the desktop personal computer 3 arranged at the standby station 85, and the image Im4 is displayed on the display of the mobile terminal 4 carried by the worker at the standby station 85.

  For example, when the gas cloud range 89 covers the passage around the gas leak point 88 as in the image Im5 shown in FIG. 13, the gas leak point path calculation unit 109 does not overlap the gas cloud range 89. The shortest path cannot be calculated (No in step S13). In this case, the gas leak location path calculation unit 109 identifies the route with the lowest gas concentration among the routes that can be accessed from the position of the standby location 85 to the position of the gas leak location 88 as the final candidate route (step S15). The method for calculating the gas concentration of the gas cloud is the same as in step S10.

  The gas concentration safety determination unit 111 determines whether or not the gas concentration of the final candidate route specified in step S15 is equal to or less than the dangerous concentration described in step S11 (step S16). If the gas concentration of the final candidate route is less than or equal to the dangerous concentration (Yes in step S16), an image (not shown) indicating the final candidate route is displayed (step S17). That is, the control processing unit 10 outputs the image data of the image to the display control unit 100, and the display control unit 100 causes the display unit 13 to display an image indicating the final candidate path. Further, the control processing unit 10 controls the interface unit 12 to output the image data of the image to the desktop personal computer 3 and the mobile terminal 4. As a result, an image showing the final candidate route is displayed on the display of the desktop personal computer 3 arranged in the standby place 85, and the final candidate route is shown on the display of the mobile terminal 4 carried by the worker in the standby place 85. An image is displayed.

  When the gas concentration of the final candidate route exceeds the dangerous concentration (No in step S16), the evacuation route calculation unit 112 (second calculation unit) performs the shortest route (third shortest route) from the waiting place 85 to the evacuation point. Route) is calculated (step S18). The evacuation points are the entrances 82a and 82b.

  The calculation of the shortest route from the standby station 85 to the evacuation site will be described in detail. The evacuation route calculation unit 112 stores the position information of the gas cloud range 89 identified in step S1, the position information of the standby station 85 stored in the standby station position storage unit 106 (second storage unit), and the evacuation position storage. Using the evacuation position information stored in the unit 108 and the passage network data stored in the passage network data storage unit 101, the shortest route from the waiting place 85 to the evacuation point is calculated (step S18). At this time, referring to FIG. 13, the evacuation route calculation unit 112 includes the passage 86 that overlaps the gas cloud range 89 from the passage network data stored in the passage network data storage unit 101, and the passage 86. The shortest path is calculated by excluding the branch points 87 (here, the passages 86a to 86g and the branch points 87a to 87g).

  As shown in FIG. 14, the evacuation route calculation unit 112 generates image data of an image Im6 indicating the shortest route 93 (third shortest route) calculated in step S15. The image Im6 differs from the image Im5 shown in FIG. 13 in that a shortest path 93 is added. Since the gas cloud range 89 extends to the passage 86e connected to the entrance / exit 82b, the shortest path toward the entrance / exit 82b is not selected, and the shortest path 93 toward the entrance / exit 82a is selected.

  An image Im6 indicating the shortest path 93 is displayed (step S19). That is, the control processing unit 10 outputs the image data of the image Im6 to the display control unit 100, and the display control unit 100 causes the display unit 13 to display the image Im6 indicated by the image data. In addition, the control processing unit 10 controls the interface unit 12 to output the image data of the image Im6 to the desktop personal computer 3 and the mobile terminal 4. As a result, the image Im6 is displayed on the display of the desktop personal computer 3 arranged in the standby station 85, and the image Im4 is displayed on the display of the mobile terminal 4 carried by the worker in the standby station 85.

  Up to this point, the worker is still in the waiting area 85. With the shortest path to the gas leaking point 88 displayed on the display of the mobile terminal 4 carried by the worker (steps S5, S12, S14, S17), the worker carries the mobile terminal 4, Head to gas leak point 88. The mobile terminal position acquisition unit 107 (fourth acquisition unit) controls the interface unit 12 to acquire the position information of the current position of the mobile terminal 4 at the first interval, and updates the position information (step S6). ). Further, the gas cloud processing unit 103 acquires the position information (second position information) of the gas cloud range 89 at the second interval, and updates the position information (step S6). The first interval and the second interval are time intervals shorter than an estimated time required for the worker to leave the waiting place 85 and reach the gas leak point 88 (for example, an interval of 30 seconds). The first interval and the second interval may be the same or different.

  The arrival determination unit 113 (third determination unit) uses the position indicated by the position information updated in step S6 (the current position of the mobile terminal 4, that is, the current position of the worker), so that the worker can It is determined whether or not the leakage point 88 has been reached (step S7). For example, if the difference between the current position of the worker and the position of the gas leak point 88 specified in step S <b> 2 is within several tens of meters, the arrival determination unit 113 has reached the gas leak point 88. (Yes in step S7). Thereby, the control processing unit 10 ends the operation of the navigation system 1000 according to the present embodiment.

  When the arrival determination unit 113 determines that the worker has not reached the gas leak point 88 (No in step S7), the gas cloud processing unit 103 detects the gas leaked from the gas leak point 88 specified in step S2. The position of the gas cloud range 89 generated by the above is specified (step S8). As the position of the gas cloud range 89, the position information updated in step S6 is used. The process of step S8 is the same as step S1.

  The gas cloud safety determination unit 110 uses the position information of the gas cloud range 89 specified in step S8 and the shortest path 91 calculated in step S3, so that the gas cloud range 89 overlaps the shortest path 91. It is determined whether or not there is (step S9). The shortest path is the shortest path 91 calculated in step S3 in the case of steps S5 and S12, the shortest path 92 calculated in step S13 in the case of step S14, and is calculated in step S15 in the case of step S17. The final candidate route (not shown). While the worker is heading toward the gas leak point 88, it is determined whether or not the gas cloud range 89 extends to the shortest path.

  If the gas cloud safety determination unit 110 determines that the shortest path does not overlap the gas cloud range 89 (No in step S9), the gas cloud safety determination unit 110 proceeds to step S6. On the other hand, when the gas cloud safety determination unit 110 determines that the shortest path overlaps the gas cloud range 89 (Yes in step S9), that is, the gas cloud range 89 extends to the shortest path. If it is determined that there is, the process proceeds to step S10.

  The main effects of this embodiment will be described. Referring to FIGS. 1A and 10, when a gas leak occurs in the plant, the worker goes to the gas leak point 88 and works to stop the gas leak. In the navigation apparatus 1 according to the present embodiment, the output unit (the control processing unit 10 or a combination of the control processing unit 10 and the interface unit 12) is connected from the standby place 85 (predetermined position) to the gas leaking point 88. When the shortest path 91 (first shortest path) does not overlap the gas cloud range 89 (in other words, when the shortest path 91 is out of the gas cloud range 89), an image of the shortest path 91 is displayed. Image data is output (step S5). As a result, an image showing the shortest path 91 is displayed on the display unit 13 of the navigation apparatus 1 or displayed on the display of the desktop personal computer 3 provided in the waiting place 85, or the mobile terminal 4 carried by the worker. It can be displayed on the display. Therefore, according to the navigation apparatus 1 which concerns on this embodiment, a worker can be navigated to the gas leak location 88 safely and quickly.

  Referring to FIG. 11, according to navigation device 1 according to the present embodiment, even if gas cloud range 89 overlaps shortest path 91 (first shortest path) (Yes in step S4), the gas concentration However, if it is less than the dangerous concentration (Yes in Step S11), the output unit outputs image data of an image indicating the shortest path 91 (Step S12). Therefore, it is possible to navigate the worker to the gas leak point 88 safely and quickly.

  Referring to FIG. 12, according to the navigation device 1 according to the present embodiment, when the gas concentration exceeds the dangerous concentration (No in step S <b> 11), the gas leak location route calculation unit 109 includes the passage network 83. Among them, a path that overlaps the gas cloud range 89 is excluded, and a shortest path 92 (second shortest path) that can reach the position of the gas leaking point 88 from the position of the waiting place 85 (current position of the mobile terminal 4). The output unit calculates and outputs image data of an image indicating the shortest path 92 (step S14). According to the present embodiment, when the gas concentration exceeds the dangerous concentration, image data of an image indicating the shortest path 92 that does not overlap the gas cloud range 89 is output. Therefore, it is possible to navigate the worker to the gas leak point 88 safely and quickly.

  Referring to FIG. 14, according to navigation device 1 according to the present embodiment, gas leak location path calculation unit 109 cannot calculate shortest path 92 (second shortest path) (No in step S13). ), A final candidate route that is a final candidate of the route to the gas leaking point 88 is calculated (step S15). When the gas concentration safety determination unit 111 determines that the gas concentration of the final candidate route exceeds the dangerous concentration (No in step S16), the evacuation route calculation unit 112 determines the position of the waiting place 85 (the current position of the mobile terminal 4). The shortest path 93 (third shortest path) that can reach the position of the evacuation point from the position is calculated (step S18). The output unit outputs image data of an image indicating the shortest path 93 (step S19). Therefore, the worker can be safely and quickly navigated to the evacuation site.

  With reference to FIG.8 and FIG.9, according to the navigation apparatus 1 which concerns on this embodiment, when an operator has not reached the position of the gas leak location 88 (No in step S7), a gas cloud safety determination unit 110 determines whether or not the first shortest path (for example, the shortest path 91 shown in FIG. 11) overlaps the gas cloud range 89 indicated by the updated position information of the gas cloud range (step S110). S9). When the first shortest path overlaps the gas cloud range 89 indicated by the updated position information of the gas cloud range (Yes in step S9), the gas concentration safety determination unit 111 determines that the updated gas cloud It is determined whether or not the gas concentration in the gas cloud range 89 indicated by the position information of the range is equal to or less than the dangerous concentration (step S11). When the gas concentration in the gas cloud range indicated by the updated position information of the gas cloud range exceeds the dangerous concentration (No in step S11), the gas leak location path calculation unit 109 displays the current location of the mobile terminal 4. A second shortest path (for example, the shortest path 92 shown in FIG. 12) that can reach the position of the gas leak point 88 from the position is calculated (Yes in step S13). The output unit outputs image data of an image indicating the second shortest path (step S14).

  As a result, the worker carrying the mobile terminal 4 is in the middle of heading for the gas leaking point 88, and the range of the gas cloud on the shortest path (first shortest path) from the position of the waiting place 85 to the position of the gas leaking point 88 is reached. And the gas concentration in the gas cloud exceeds the dangerous concentration, the shortest path (second shortest path) from the current position of the worker to the position of the gas leak point 88 is calculated. Therefore, it is possible to navigate the worker to the gas leak point 88 safely and quickly.

  A modification of the gas cloud range 89 will be described. FIG. 15 is an image diagram showing a modified example of the gas cloud range 89 and an image including the shortest path 91. Vectors 96, 97a, and 97b are added to the range 89 of the gas cloud. The vector 96 indicates the direction in which the gas cloud spread is the largest. The pair of vectors 97a and 97b indicate that the gas cloud is within the range defined by these directions.

  The gas cloud range 89 is divided into a region indicated by a light color and a region indicated by a dark color. The region shown in light color indicates that the gas concentration is relatively low and safe, and the region shown in dark color indicates that the gas concentration is relatively high and unsafe.

(Summary of embodiment)
The navigation apparatus according to the first aspect of the present embodiment includes a first storage unit that stores passage network data indicating a passage network provided in the plant in advance, and gas leakage occurs in the plant. A first acquisition unit that acquires first position information indicating the position of a gas leak location, and a second acquisition unit that acquires second position information indicating the position of the range of the gas cloud generated by the gas leak And using the passage network, the predetermined information using the passage network data, the first position information, the second position information, and the third position information indicating a predetermined position in the plant. A calculation unit that calculates the shortest path that does not overlap with the range of the gas cloud and can output the image data of the image indicating the shortest path.

  When a gas leak occurs in the plant, the worker goes to the gas leak point and works to stop the gas leak. The predetermined position means the position of the worker's waiting place and the current position of the mobile terminal carried by the worker. In the navigation device according to the first aspect of the present invention, the calculation unit calculates the shortest path that can reach the position of the gas leakage point from a predetermined position and does not overlap the range of the gas cloud, and the output unit calculates the shortest path. The image data of the image showing the route is output. Thus, for example, an image showing the shortest path is displayed on the display unit of the navigation device, displayed on the display of a desktop PC provided in the worker's waiting area, or displayed on the mobile terminal carried by the worker Can be displayed. Therefore, according to the navigation apparatus which concerns on the 1st aspect of this embodiment, a worker can be navigated to a gas leak location safely and quickly.

  In the above configuration, the calculation unit uses the passage network data, the first position information, and the third position information, and uses the passage network to determine the location of the gas leak from the predetermined position. A first calculation unit that calculates a first shortest path that is a shortest path that can reach a position; and whether or not the first shortest path overlaps a range of the gas cloud indicated by the second position information. A first determination unit that determines whether or not.

  This configuration is a subordinate concept of the calculation unit. A 1st determination part determines whether the shortest path (1st shortest path) from a predetermined position to a gas leak location has overlapped with the range of a gas cloud. When the first shortest path does not overlap with the range of the gas cloud (in other words, when the first shortest path is out of the range of the gas cloud), the output unit displays an image indicating the first shortest path. Output image data.

  In the above configuration, when it is determined that the third acquisition unit that acquires the concentration information indicating the gas concentration of the gas cloud and the first shortest path overlaps the range of the gas cloud, the concentration information A second determination unit that determines whether or not the gas concentration shown is equal to or lower than a predetermined dangerous concentration, and the output unit determines that the gas concentration is equal to or lower than the dangerous concentration, Image data of an image indicating the first shortest path is output.

  The predetermined dangerous concentration is, for example, a concentration that may cause a gas explosion. According to this configuration, even if the range of the gas cloud overlaps the shortest path, image data of an image indicating the shortest path is output if the gas concentration is equal to or less than a predetermined dangerous concentration. Therefore, it is possible to navigate the worker to the gas leak point safely and quickly.

  The said structure WHEREIN: The said 1st calculation part excludes the channel | path which overlapped the range of the said gas cloud among the said channel networks, when it determines with the said gas concentration exceeding the said dangerous concentration. Using the network data, the first position information, and the third position information, the second shortest path that is the shortest path that can reach the position of the gas leak location from the predetermined position using the passage network And the output unit outputs image data of an image indicating the second shortest path.

  According to this configuration, when the gas concentration exceeds the dangerous concentration, image data of an image indicating the second shortest path, that is, the shortest path that does not overlap with the range of the gas cloud is output. Therefore, it is possible to navigate the worker to the gas leak point safely and quickly.

  In the above configuration, when the first calculation unit cannot calculate the second shortest path, the gas concentration is the lowest among the paths that can be accessed from the predetermined position to the position of the gas leakage point. The route is calculated as a final candidate route, and the second determination unit determines whether or not the gas concentration of the final candidate route is equal to or less than the dangerous concentration, and preliminarily stores fourth position information indicating the position of the evacuation site. The second storage unit for storing and the passage excluding the passage overlapping with the gas cloud in the passage network when it is determined that the gas concentration of the final candidate route exceeds the dangerous concentration Using the network data, the third position information, and the fourth position information, a third shortest path that is the shortest path that can reach the position of the evacuation site from the predetermined position using the passage network Second calculation to calculate Further comprising a section, wherein the output unit outputs the image data of the image indicating the third shortest route.

  According to this configuration, when the second shortest path cannot be calculated, the first calculation unit calculates a final candidate path that is a final candidate of a path to the gas leak point. When the second determination unit determines that the gas concentration of the final candidate route exceeds the dangerous concentration, the second calculation unit calculates the shortest route (third shortest route) that can reach the position of the evacuation point from a predetermined position. Route). The output unit outputs image data of an image indicating the third shortest path. Therefore, the worker can be safely and quickly navigated to the evacuation site.

  In the above configuration, the predetermined position is set as a current position of the mobile terminal, the third position information indicating the predetermined position is acquired from the mobile terminal at predetermined intervals, and the third position information is updated. Whether or not the worker carrying the mobile terminal has reached the position of the gas leak location using the fourth acquisition unit, the first position information, and the updated third position information A third determination unit for determining the second position information, acquiring the second position information at a predetermined interval, updating the second position information, and When it is determined that the worker has not reached the position of the gas leak point, the determination unit of the gas cloud indicated by the updated second position information indicates the first shortest path. It is determined whether or not it overlaps the range, the second determination unit is When it is determined that the first shortest path overlaps the range of the gas cloud indicated by the updated second position information, the gas cloud indicated by the updated second position information The gas concentration is less than or equal to the dangerous concentration, and the first calculation unit determines that the gas concentration of the gas cloud indicated by the updated second position information is the dangerous concentration. The passage network data excluding the passage that overlaps the range of the gas cloud indicated by the updated second position information in the passage network when it is determined that the first position is exceeded; Using the information and the updated third position information, calculate the second shortest path that can reach the position of the gas leak location from the current position using the passage network, the output unit, Calculated using the updated third position information And it outputs the image data of an image showing a second shortest path is.

  According to this configuration, the worker carrying the mobile terminal is on the way to the gas leak location, and the gas cloud range overlaps the shortest route (first shortest route) from the predetermined position to the gas leak location. When the gas concentration of the gas cloud exceeds the dangerous concentration, the shortest path (second shortest path) from the current position of the worker to the position of the gas leak point is calculated. Therefore, it is possible to navigate the worker to the gas leak point safely and quickly.

  The navigation method according to the second aspect of the present embodiment includes a first step of acquiring first position information indicating a position of a gas leak location where a gas leak has occurred in the plant, and the gas leak. A second step of acquiring second position information indicating a position of a range of the generated gas cloud, passage network data indicating a passage network provided in the plant, the first position information, the second And the third position information indicating a predetermined position in the plant, the gas cloud can be reached from the predetermined position to the position of the gas leak using the passage network. A third step of calculating a shortest path that does not overlap with the range; and a fourth step of outputting image data of an image indicating the shortest path.

  According to the navigation method concerning the 2nd situation of this embodiment, it has the same operation effect as the navigation device concerning the 1st situation of this embodiment.

  This application is based on Japanese Patent Application No. 2015-197769 filed on October 5, 2015, the contents of which are included in the present application.

  In order to express the present invention, the present invention has been properly and fully described through the embodiments with reference to the drawings. However, those skilled in the art can easily change and / or improve the above-described embodiments. It should be recognized that this is possible. Therefore, unless the modifications or improvements implemented by those skilled in the art are at a level that departs from the scope of the claims recited in the claims, the modifications or improvements are not covered by the claims. To be construed as inclusive.

  According to the present invention, a navigation device and a navigation method can be provided.

Claims (7)

A first storage unit for preliminarily storing passage network data indicating the passage network provided in the plant;
A first acquisition unit that acquires first position information indicating a position of a gas leak point where a gas leak occurs in the plant;
A second acquisition unit that acquires second position information indicating a position of a range of a gas cloud generated by the gas leakage;
The predetermined position using the passage network using the passage network data, the first position information, the second position information, and third position information indicating a predetermined position in the plant. A calculation unit that calculates the shortest path that does not overlap with the range of the gas cloud, which can reach the position of the gas leak point from
An output unit that outputs image data of an image indicating the shortest path. The calculation unit includes:
Using the passage network data, the first position information, and the third position information, the shortest path that can reach the position of the gas leak point from the predetermined position using the passage network. A first calculation unit for calculating one shortest path;
The navigation apparatus according to claim 1, further comprising: a first determination unit that determines whether or not the first shortest path overlaps a range of the gas cloud indicated by the second position information. A third acquisition unit that acquires concentration information indicating the gas concentration of the gas cloud;
A second determination unit configured to determine whether or not the gas concentration indicated by the concentration information is equal to or lower than a predetermined dangerous concentration when it is determined that the first shortest path overlaps the range of the gas cloud; And further comprising
The navigation device according to claim 2, wherein the output unit outputs image data of an image indicating the first shortest path when the gas concentration is determined to be equal to or less than the dangerous concentration. The first calculation unit, when it is determined that the gas concentration exceeds the dangerous concentration, the passage network data excluding a passage overlapping with a range of the gas cloud in the passage network, Using the first position information and the third position information, the second shortest path, which is the shortest path that can reach the position of the gas leak point from the predetermined position using the passage network, is calculated,
The navigation device according to claim 3, wherein the output unit outputs image data of an image indicating the second shortest path. If the first shortest path cannot be calculated, the first calculation unit selects a path with the lowest gas concentration from among the paths that can be accessed from the predetermined position to the position of the gas leak point. As a route,
The second determination unit determines whether or not the gas concentration of the final candidate route is equal to or less than the dangerous concentration;
A second storage unit for previously storing fourth position information indicating the position of the evacuation point;
When it is determined that the gas concentration of the final candidate route exceeds the dangerous concentration, the passage network data excluding the passage overlapping with the gas cloud in the passage network, the third position information And a second calculation unit that calculates a third shortest route that is the shortest route that can reach the position of the evacuation site from the predetermined position using the passage network using the fourth position information; Further comprising
The navigation device according to claim 4, wherein the output unit outputs image data of an image indicating the third shortest path. The fourth acquisition for updating the third position information by setting the predetermined position as the current position of the mobile terminal and acquiring the third position information indicating the predetermined position from the mobile terminal at predetermined intervals. And
Third determination for determining whether or not an operator carrying the mobile terminal has reached the position of the gas leakage location using the first position information and the updated third position information And further comprising
The second acquisition unit acquires the second position information at a predetermined interval, updates the second position information,
When the first determination unit determines that the worker has not reached the position of the gas leak point, the first shortest path is indicated by the updated second position information. Determine whether it overlaps the range of the gas cloud,
The second determination unit, when it is determined that the first shortest path overlaps the range of the gas cloud indicated by the updated second position information, the updated second Determining whether the gas concentration of the gas cloud indicated by the position information is less than or equal to the dangerous concentration;
The first calculation unit is updated in the passage network when it is determined that the gas concentration of the gas cloud indicated by the updated second position information exceeds the dangerous concentration. The passage using the passage network data excluding the passage overlapping the range of the gas cloud indicated by the second position information, the first position information, and the updated third position information. Calculate the second shortest path that can reach the position of the gas leak location from the current position using a net,
The navigation device according to claim 4 or 5, wherein the output unit outputs image data of an image indicating the second shortest path calculated by using the updated third position information. A first step in which a first acquisition unit acquires first position information indicating a position of a gas leak point where a gas leak occurs in the plant;
A second step in which a second acquisition unit acquires second position information indicating a position of a range of a gas cloud caused by the gas leakage;
The calculation unit includes passage network data indicating a passage network provided in the plant, the first position information, the second position information, and third position information indicating a predetermined position in the plant. A third step of calculating a shortest path that does not overlap with a range of the gas cloud that can reach the position of the gas leakage point from the predetermined position using the passage network;
And a fourth step in which the output unit outputs image data of an image indicating the shortest path.

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