JP2019199340A - Surrounding environment information provision method for elevator and surrounding environment information provision system for elevator - Google Patents

Abstract

To utilize environment information surrounding an elevator and improve convenience for a user.SOLUTION: On the basis of position information of an elevator 300, environment information surrounding a building in which the elevator 300 is installed is extracted, as surrounding information 350, from environment information acquired via a communication device 210, and is transmitted to the elevator 300. If the surrounding information 350 affects traffic surrounding the building in which the elevator is installed and accepts an instruction to travel in a predetermined reference floor direction, the surrounding information 350 and alert information 370 are output to an in-car display 323.SELECTED DRAWING: Figure 14

Description

  The present invention relates to a technology for providing elevator surrounding information to an elevator user, and more particularly, to a technology for selectively providing information that affects traffic around a building in which the elevator is installed.

  Environmental information around the elevator, such as weather information, is used for elevator operation control. For example, Patent Document 1 includes a “weather information detection device that detects information related to weather. The elevator control device directly affects the car due to weather changes based on weather information detected by the weather information detection device. For example, if a lightning approach is detected by a lightning detection device of a weather information detection device, and there is a possibility of lightning strike in the vicinity, the car is moved away from the floor where there is no direct lightning strike effect. Evacuate (summary excerpt). "An elevator control device is disclosed.

JP 2003-267636 A

  According to the technology disclosed in Patent Document 1, it is possible to ensure the safety of the user and prevent the car from being damaged by the surrounding environment information. However, the acquired environmental information is used only for operation control, and it is not fully utilized for the purpose of improving the convenience for the user.

  This invention is made | formed in view of the said situation, and it aims at providing the technique which utilizes the environmental information around an elevator and improves a user's convenience.

  The present invention is an elevator ambient environment information providing method for providing an elevator user with environment information around a building in which the elevator is installed, and based on the position information of the elevator, via a communication device. The environmental information around the building where the elevator is installed is extracted as ambient information from the environmental information acquired in this way and transmitted to the elevator, and the ambient information is transmitted to traffic around the building. When an instruction to travel in the direction of a predetermined reference floor is received, the surrounding information and the alert information are output to a display in the car.

  In addition, the present invention uses the environmental information around the elevator to improve the convenience for the user. Problems, configurations, and effects other than those described above will become apparent from the following description of embodiments.

It is a whole block diagram of the surrounding environment information provision system of embodiment of this invention. (A) And (b) is a functional block diagram and a hardware block diagram of the monitoring server of embodiment of this invention, respectively. It is explanatory drawing for demonstrating an example of the lightning information of embodiment of this invention. (A)-(c) is explanatory drawing for demonstrating an example of the lightning information of embodiment of this invention. It is explanatory drawing for demonstrating an example of the local time slot | zone information of embodiment of this invention. (A) And (b) is explanatory drawing for demonstrating an example of activity level map information of embodiment of this invention. It is explanatory drawing for demonstrating the calculation method of the position of the lightning of embodiment of this invention. It is explanatory drawing for demonstrating an example of the elevator information of embodiment of this invention. (A)-(c) is explanatory drawing for demonstrating an example of the surrounding information distributed to each elevator from the monitoring server of embodiment of this invention. (A), (b) is explanatory drawing for demonstrating the structure of hall equipment and a passenger car of the elevator of embodiment of this invention, (c) is the elevator control apparatus of embodiment of this invention. It is a functional block diagram. (A) And (b) is explanatory drawing for demonstrating an example of the pattern information and alerting information of embodiment of this invention, respectively. It is explanatory drawing for demonstrating the direction calculation method of the lightning of embodiment of this invention. It is explanatory drawing for demonstrating the example of a display screen of embodiment of this invention. It is a flowchart of the surrounding environment information provision process of the elevator of embodiment of this invention.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. Hereinafter, in this specification, those having the same function are denoted by the same reference numerals unless otherwise specified, and repeated description is omitted.

  In the present embodiment, when the elevator receives an instruction for traveling in a predetermined reference floor direction, the environment information around the elevator received via the communication device is used to indicate the surroundings of the building where the elevator is installed. Information that affects traffic is extracted and displayed on the display in the car.

  Hereinafter, in this embodiment, a case where lightning information that is lightning occurrence information among weather information is used as environmental information will be described as an example. Lightning information is acquired at the monitoring center in accordance with the update timing. Then, processing is performed at the monitoring center, and the surrounding information is selectively provided to each elevator with which the monitoring center has a maintenance contract.

  Hereinafter, the surrounding environment information provision system of this embodiment which implement | achieves this is demonstrated.

[Ambient environment information provision system]
FIG. 1 is an overall configuration diagram of a surrounding environment information providing system 100 according to the present embodiment. As shown in the figure, the ambient environment information providing system 100 of this embodiment includes a monitoring server 200 and an elevator 300. Here, one elevator 300 is shown, but a plurality of elevators 300 may be provided.

  The monitoring server 200 is an information processing device prepared for management and monitoring of the elevator 300 that has a maintenance contract, and is installed in a monitoring center, for example. Hereinafter, the elevator 300 that has made a maintenance contract is referred to as a monitored elevator 300.

  In addition, the monitoring server 200 acquires and accumulates lightning information from an external device such as the Web server 400 via the network 110 such as the Internet. The monitoring server 200 processes the acquired lightning information, and provides processed lightning information in a range necessary for each monitored elevator 300 via the network 110 as ambient information.

  Note that the monitoring server 200 and each elevator 300 may be connected to a dedicated network such as an in-house LAN that is different from the network 110. In this case, the aforementioned lightning information is provided via this dedicated network.

  The elevator 300 is provided in a building such as a building. The elevator 300 displays the lightning information received from the monitoring server 200 on the display of the car and / or hall (stop) as necessary.

  The elevator 300 includes an elevator control device 310, a car 320, and a hall facility 330.

  The elevator control device 310 controls the operation of the entire elevator 300 including the passenger car 320. Here, a case where there is one car 320 is illustrated, but a plurality of cars 320 may be provided. The elevator control device 310 may be provided for each car 320 or may be provided for one elevator 300 to control the operation and operation of a plurality of cars.

  The main rope, the counterweight, the car, the hoisting machine, and the like that constitute the elevator 300 are the same as the previous configuration, and thus the description thereof is omitted.

[Monitoring server]
The monitoring server 200 will be described. A functional block diagram of the monitoring server 200 is shown in FIG. The monitoring server 200 includes a server communication unit 210, a server control unit 220, and a server storage unit 230.

  The server communication unit 210 performs communication via the network 110.

  The server storage unit 230 stores data used for processing, data obtained during processing, processed data, and the like in the monitoring server 200. As shown in the figure, lightning information 240, processed lightning information 250, and elevator information 280 are stored. The processed lightning information 250 includes local time zone information 260, activity map information 270, and a position 271. Details of each information will be described later.

  The server control unit 220 performs processing for realizing overall control of the monitoring server 200, monitoring of the elevator 300, and the like. As shown in the figure, the server control unit 220 includes a lightning information acquisition unit 221, a lightning information processing unit 222, and a lightning information distribution unit 223.

  The lightning information acquisition unit 221 downloads the latest lightning information in accordance with the timing at which the web server 400 that owns the lightning information updates the lightning information, and stores it in the server storage unit 230 as the lightning information 240.

  The lightning information 240 is information obtained by analyzing and digitizing the intensity of lightning and the possibility of lightning in units of predetermined grids, and also makes predictions up to a predetermined time ahead. The web server 400 that holds the lightning information updates the lightning information at predetermined time intervals, for example, every 10 minutes.

  Hereinafter, information obtained by quantifying the analysis result is referred to as activity. The greater the value of activity, the more intense the activity. For example, when the activity level is expressed in five stages from 0 to 4, it is as follows. Activity level 4 is “violent lightning”, that is, a situation in which intense lightning occurs, and a large number of lightning strikes, and activity level 3 is “moderately heavy lightning”, that is, moderately intense lightning and lightning strikes. The activity level 2 is “thunder”, that is, lightning occurs, lightning can be heard or thunder can be heard, and the possibility of lightning strikes is high. “There is a possibility”, that is, a situation that is not currently occurring but a possibility of lightning is generated, and an activity level of 0 represents “no lightning”, that is, a situation that no lightning is possible.

  An example of the stored lightning information 240 is shown in FIGS. 3 and 4A to 4C. In the present embodiment, a predetermined unit lattice is referred to as an observation mesh.

  The observation mesh has a size of about 1 km square, and is expressed by a latitude of 0.01 ° in terms of latitude and longitude. As shown in these figures, the latitude (north latitude) of the center of the observation mesh is in the range from 35.98 ° to 36.02 °, and the longitude (east longitude) is from 139.98 ° to 140.02 °. Indicates a case where information is received. The prediction is performed every 10 minutes until 70 minutes later. Furthermore, it is assumed that the lightning information 240 is provided every 10 minutes. The lightning information prediction date and time (current date and time) is assumed to be 10:00 on October 10.

  Each observation mesh is assigned an observation mesh number that uniquely identifies the observation mesh. Here, as shown in FIG. 4A, values from 001 to 025 are given.

  As shown in FIGS. 4B and 4C, the lightning information 240 stores observation mesh information 240m for each observation mesh. The observation mesh information includes a prediction date and time 241 that is the date and time when the lightning information is created, center position information (north latitude and east longitude) 242 of the observation mesh, an activity 243 from the present to a predetermined future time, and an observation mesh number. 244. Here, the case where the activity level 243 from 70 minutes after every 10 minutes from the present date and time is included is illustrated.

  Every time new lightning information 240 is stored in the server storage unit 230, the lightning information processing unit 222 processes the newly stored lightning information 240 to generate processed lightning information 250. In the present embodiment, as the processing lightning information 250, the local time zone information 260, the activity map information 270, and the position 251 are generated as described above.

  The local time zone information 260 is information that stores a time zone in which it is predicted that “lightning” and “violent lightning” are likely to occur for each observation mesh of the lightning information 240.

  As shown in FIG. 5, in the local time zone information 260, the observation mesh number (No.) 261, the center position information of the observation mesh (north latitude 262, east longitude 263), and the occurrence time zone 264 are associated with each other. Information.

  The lightning information processing unit 222 extracts items of the same name from each observation mesh information 240m of the lightning information 240, and stores them in the observation mesh number 261 and center position information (north latitude 262, east longitude 263), respectively.

  The lightning information processing unit 222 extracts a time zone in which a value equal to or greater than a predetermined value is registered in the activity level 243 from the lightning information 240 and stores the time zone in the occurrence time zone 264.

  In the present embodiment, for example, a time zone in which the activity level 243 is 2 or more is extracted as a time zone in which “lightning” is easy, and a time zone in which the activity level is 3 or more is easily generated as a time zone. H.264.

  As shown in FIG. 5, for example, in the observation mesh 001 whose latitude information at the center is 35.98 ° north latitude and longitude information at the center is 139.98 ° east longitude, the activity 243 for each time zone of the observation mesh information 240m is Is as follows. 4 from 14:00 to 10 minutes, 4 after 10-20 minutes, 2 after 20-30 minutes, 2, after 30-40 minutes, 1, after 40-50 minutes, after 50-60 minutes 0, 0 after 60-70 minutes.

  Since the activity in the time zone from 14:00 to 14:40 is 2 or more, the lightning information processing unit 222 registers this time zone as “lightning” in the generation time zone 264. In addition, since the activity level in the time zone from 14:00 to 14:20 is 3 or more, the lightning information processing unit 222 registers this time zone as “violent lightning” in the generation time zone 264.

  The activity level map information 270 is information obtained by mapping the activity level of the lightning information 240 for each time zone.

  The lightning information processing unit 222 arranges the activity of each observation mesh in the same time zone as shown in FIG. 6A, and creates activity map information 270. An example of the created activity map information 270 is shown in FIG. As shown in the figure, the lightning information processing unit 222 maps the activity level by color to the grid corresponding to each observation mesh.

  At this time, the lightning information processing unit 222 calculates the lightning center position as the lightning position 271. The calculated lightning position 271 may be superimposed on the activity map information 270.

  Here, a method of calculating the lightning position 271 by the lightning information processing unit 222 will be described with reference to FIG.

  For example, the lightning information processing unit 222 calculates the weighted average of the center position where lightning is occurring in each time zone, using the latitude and longitude of the center position of each observation mesh and the activity, using the following formula (1). To calculate.

Here, it is assumed that the number of observation meshes is I (I is an integer of 1 or more), and each observation mesh is assigned a serial number from 1 to I. The center coordinates of lightning in each time zone are represented by f (x _I , y _I ). Note that i is an integer satisfying 1 ≦ i ≦ I.
x _i : longitude of the center of the ith observation mesh (east longitude)
y _i : Latitude (north latitude) of the center of the i-th observation mesh
a _i : Activity of the i-th observation mesh

  A specific calculation method will be described with reference to FIG. FIG. 7 illustrates an example in which the total number of observation meshes is 100, and the range of the center position of each observation mesh is 36.01 ° to 36.09 ° north latitude and 139.99 ° to 140.06 ° east longitude. I will explain.

  In this example, it is assumed that there is no observation mesh having an activity level of 1. Therefore, as shown in FIG. 7, a weighted average of the latitude and longitude of the center position of an area having an activity level of 2 or more is calculated based on the activity level.

In other words, the latitude f (x _I ) of the center of lightning is [the sum of {the product of “activity” and “latitude of the center” in all areas with activity of 2 or more}] It is calculated by dividing by the sum. Specifically, it is calculated as shown in the following formula (2).
f (x _I ) = (4 × (140.02 × 1 + 140.03 × 2)
+ 3 × (140.00 × 1 + 140.01 × 2 + 140.02 × 3 + 140.03 × 3 + 140.04 × 4 + 140.05 × 2)
+ 2 × (139.99 × 4 + 140.00 × 3 + 140.01 × 5 + 140.02 × 2 + 140.03 × 1 + 140.04 × 2 + 140.05 × 3 + 140.06 × 1)] ÷ (4 × 3 + 3 × 15 + 2 × 21 )
= 13862.35 ÷ 99
= 140.024 ・ ・ ・ (2)

Similarly, the longitude f (y _I ) of the center of lightning is [the sum of {the product of “activity” and “center longitude” of all areas with activity of 2 or more}], [the “activity” It is calculated by dividing by the sum. Specifically, it is calculated as shown in the following formula (3).
f (y _I ) = (4 × (36.05 × 2 + 36.06 × 1)
+ 3 × (36.03 × 2 + 36.04 × 4 + 36.05 × 4 + 36.06 × 2 + 36.07 × 3)
+ 2 × (36.02 × 6 + 36.03 × 3 + 36.04 × 4 + 36.05 × 1 + 36.06 × 4 + 36.07 × 2 + 36.08 × 1)]
÷ (4 × 3 + 3 × 15 + 2 × 21)
= 3568.65 ÷ 99
= 36.047 (3)

  Thus, in the example of FIG. 7, the lightning position 271 that is the center position of the lightning is calculated as (36.047 ° north latitude, 140.024 ° east longitude).

  As described above, the lightning information processing unit 222 calculates the processed lightning information 250 and stores it in the server storage unit 230.

  The lightning information distribution unit 223 distributes the lightning information 240 and the processed lightning information 250 generated by the lightning information processing unit 222 to each monitored elevator 300 as surrounding information. In the present embodiment, when the lightning information processing unit 222 newly generates the processed lightning information 250, the information on the surroundings of each monitored elevator 300 is extracted and provided by referring to the elevator information 280.

  Here, the data structure of the elevator information 280 will be described. FIG. 8 is a diagram for explaining the data configuration of the elevator information 280 of the present embodiment. As shown in the figure, the elevator information 280 is registered by associating the position information 282 of the monitoring target elevator 300 with the elevator ID 281 that is information for uniquely specifying the monitoring target elevator 300. The position information 282 of the monitoring target elevator 300 is represented by, for example, the latitude (northern latitude) and longitude (east longitude) of the location of the monitoring target elevator 300.

  Furthermore, as shown in the figure, an observation mesh number (observation mesh No) 283 including the location of each monitored elevator 300 may be further associated. Hereinafter, in the present embodiment, it is assumed that the observation mesh number 283 is also associated.

  The lightning information distribution unit 223 accesses the elevator information 280 and extracts the observation mesh number 283 of the arrangement position of each monitored elevator 300 as the arrangement mesh. And the lightning information 240 of the arrangement | positioning mesh and the predetermined process lightning information 250 are transmitted to each monitoring object elevator 300 as surrounding information.

  For example, in the elevator information 280 of FIG. 8, when the elevator ID 281 is the monitoring target elevator 300 with “AAA”, the location of the monitoring target elevator 300 is 35.991 ° north latitude and 139.992 ° east longitude. The observation mesh number 283 including this position is “007”.

  The lightning information distribution unit 223 includes the lightning information 240a that is the observation mesh information 240m with the observation mesh number “007” shown in FIG. 9A, the local time zone information 260a shown in FIG. The activity map information 270a and the lightning position 271 in a predetermined range centering on the observation mesh number “007” shown in 9 (c) are extracted and transmitted to the monitored elevator 300 as ambient information.

  Here, it is assumed that information on an observation range composed of nine observation meshes centered on the arrangement mesh is transmitted as a predetermined range. Further, in FIG. 9C, the illustration of the lightning position 271 that is information on the center position of the lightning is omitted.

  The hardware configuration of the monitoring server 200 is shown in FIG. As shown in this figure, the monitoring server 200 of this embodiment includes, for example, a CPU (Central Processing Unit) 291, a RAM (Random Access Memory) 292, a storage device 293, and an input / output interface (I / F) 294. And a communication I / F 295. These are connected via a bus 296.

  The storage device 293 is realized by, for example, one or more nonvolatile storage devices such as a hard disk device and a flash memory (including an SSD in this case).

  Each function of the server control unit 220 is realized by the CPU 291 loading a program stored in advance in the storage device 293 into the RAM 292 and executing it.

  The server storage unit 230 is built in the storage device 293. It may be constructed in an external device such as a database server capable of transmitting and receiving data to and from the monitoring server 200 via the network 110. Hereinafter, in this embodiment, for the sake of convenience, the server storage unit 230 is assumed to be built in a storage device that is mounted on or directly connected to the monitoring server 200.

  The input / output I / F 294 is an interface with an input / output device.

  The communication I / F 295 performs communication via the network 110 according to control by the server communication unit 210. The network 110 according to this embodiment includes the Internet or a LAN (Local Area Network). For example, the communication I / F 295 and the server communication unit 210 are realized by a communication device such as a NIC (Network Interface Controller), for example.

[elevator]
Next, the elevator 300 will be described.

  As shown in FIG. 10A, the hall facility 330 of the elevator 300 includes a hall button 332 and a hall display 333.

  The hall button 332 includes an ascending instruction button and a descending instruction button for receiving an ascending instruction and a descending instruction by the user, respectively. Note that the top floor includes only a descending instruction button, and the bottom floor includes only an ascending instruction button. The received instruction is transmitted to the elevator control device 310.

  Hall display 333 displays an image in accordance with an instruction from elevator control device 310. Note that the hall display 333 may have a sound output function such as a speaker.

  As shown in FIG. 10B, the car 320 includes a car destination instruction button 322 and a car display 323.

  The in-car destination instruction button 322 receives a destination floor instruction from the user. The received instruction is transmitted to the elevator control device 310.

  The in-car display 323 displays an image in accordance with an instruction from the elevator control device 310. The in-car display 323 may also have a sound output function such as a speaker.

  As shown in FIG. 1 and FIG. 10C, the elevator control device 310 includes an elevator communication unit 311, an elevator calculation unit 312, and an elevator storage unit 313.

  Similarly to the server communication unit 210, the elevator communication unit 311 performs communication via the network 110.

  Similarly to the server storage unit 230, the elevator storage unit 313 stores data used for processing, data obtained during processing, processed data, and the like in the elevator control device 310. As shown in FIG. 10C, the elevator storage unit 313 stores ambient information 350, pattern information 360, and alert information 370.

  The elevator calculation unit 312 performs control of the entire elevator control device 310 and output control to the hall display 333 and the car display 323. Here, the description will focus on output control using ambient information when the ambient information is acquired from the monitoring server 200.

  As shown in FIG. 10C, the elevator calculation unit 312 includes a surrounding information reception unit 341, a destination determination unit 342, an output necessity determination unit 343, and an output control unit 344.

  The surrounding information receiving unit 341 receives the surrounding information provided from the monitoring server 200 at a predetermined time interval via the elevator communication unit 311 and stores it in the elevator storage unit 313 as the surrounding information 350.

  The destination determination unit 342 determines the destination of the car 320. In the present embodiment, it is determined whether or not the destination of the car 320 is in a predetermined reference floor direction. The reference floor is, for example, a floor with an entrance to the outside of the building. When it is determined that traveling in the reference floor direction is instructed, the output necessity determination unit 343 is notified of this.

  In the present embodiment, the destination determination unit 342 monitors the current position of the car 320 and receives instructions from the hall button 332 and the in-car destination instruction button 322 to determine the destination.

  The destination discriminating unit 342 discriminates that the destination is in the direction of the reference floor when the current position of the car 320 is not the reference floor and traveling to the reference floor is instructed by the destination instruction button 322 in the car. . Further, in a hall other than the reference floor, when the hall button 332 instructs to travel in the reference floor direction, it is determined that the destination is the reference floor direction.

  In addition, the information on the current position of the car 320 is acquired from, for example, an operation control unit (not shown) included in the elevator control device 310. The operation control unit obtains the current position of the car 320 using, for example, a conventional method of calculating from the output of a rotation amount detection sensor attached to the hoisting machine.

  The output necessity determination unit 343 determines whether output to the hall display 333 and the in-car display 323 is necessary. When it is determined that the output is necessary, the output control unit 344 instructs the output control unit 344 to generate output data.

  In the present embodiment, the output necessity determination unit 343 requires the output to the hall display 333 according to the surrounding information 350 every time the surrounding information receiving unit 341 receives the surrounding information 350 and stores it in the elevator storage unit 313. Determine no.

  For example, when a sign of occurrence of a natural disaster such as a lightning strike is included, it is determined that a warning output is necessary as it affects traffic around a building where the elevator 300 is installed.

  When it is determined that output is necessary, the output necessity determination unit 343 determines whether output to the in-car display 323 is necessary according to the determination result of the destination determination unit 342. Here, when the destination discriminating unit 342 discriminates that traveling in the reference floor direction is instructed, the output control unit 344 is instructed to output from the in-car display 323 as well.

  When determining the necessity of output according to the surrounding information 350, the output necessity determining unit 343 determines the pattern of the surrounding information 350 according to the pattern information 360, and alerts the necessity of output according to the pattern. This is determined by 370.

  Here, the pattern information 360 and the alert information 370 used when the output necessity determination unit 343 determines whether or not the output is necessary will be described.

  The pattern information 360 categorizes lightning states into several patterns. In this embodiment, it classifies according to the activity level for every time slot | zone.

  FIG. 11A shows an example in which lightning states are classified into four according to the activity for each time zone. In the pattern information 360, for each pattern 361 that is information for specifying a pattern, a thunder state 362 and the latest activity information 363 as a determination condition based on the activity are associated and registered in advance.

  In the alert information 370, alert contents 372 to be output from the car display 323 and the hall display 333 are registered for each pattern 361 of the pattern information 360. Here, for the pattern 361 when output is not required, information indicating that output is not required is registered in the alert content 372.

  In the pattern information 360 of FIG. 11A, the pattern P0 is the activity level 363 in the activity level information 363 and the activity level predicted after 10 minutes (after 10 to 60 minutes). Are all 1 or less. In this case, since it is determined that there is no lightning strike and does not approach the elevator 300, “no lightning” is registered in the lightning state 362. In addition, since it is not necessary to output an alert, “output unnecessary” is registered in the alert content 372 of the alert information 370.

  The pattern P1 is a case where, in the activity level information 363, the activity level at the prediction time point is 1 or less, but the predicted activity level after 10 minutes is 2 or more. In this case, lightning will approach the vicinity of the elevator 300. Therefore, “Thunder is approaching” is registered in the lightning state 362. Also, the alert contents 372 include “careful attention to lightning occurrence time zones and use of elevators during that time zone” and “directions where lightning is currently occurring and the direction in which lightning will proceed from now on. If you go out, be careful about lightning.

  The pattern P2 is a case where the activity level at the time of prediction is 2 in the activity level information 363. In this case, lightning is currently occurring in the observation mesh including the location of the elevator 300. Therefore, “thunder is coming” is registered in the lightning state 362. The alert content 372 also includes “lightning occurrence time zone and the use of elevators should be avoided as much as possible because lightning strikes may stop the elevator” and “lightning will go out in the future. Information that signifies "Those who are careful about thunder" is registered.

  The pattern P3 is a case where the activity level at the time of prediction is 3 or more in the activity level information 363. In this case, intense lightning is currently occurring in the observation mesh including the location of the elevator 300. Therefore, “the intense lightning is coming” is registered in the lightning state 362. The alert content 372 also includes: “Through the time of lightning occurrence and the elevator may stop due to a lightning strike, refrain from using the elevator as much as possible except in the event of an emergency” and “ Information is registered that means "Those who go out should take care of lightning."

  The output necessity determination unit 343 refers to the lightning information 240a of the registered ambient information 350, and identifies the corresponding pattern 361 based on the activity after 0-10 minutes and the activity after 10-60 minutes. Then, it is determined whether or not it is necessary to output the specified pattern 361 with reference to the alert information 370.

  If the output is required, the alert content 372 that is the output content is extracted from the alert information 370. Then, using this alerting content 372 and the registered surrounding information 350, output data is generated and an output instruction is given to the output control unit 344.

  When it is determined that output is necessary, the output necessity determination unit 343 according to the present embodiment uses the surrounding information 350 to calculate the direction of lightning based on the position of the elevator 300.

  Here, a method for calculating the direction of lightning by the output necessity determination unit 343 will be described. Here, the lightning position 271 received from the monitoring server 200 is used.

  For example, the output necessity determination unit 343 compares the latitude / longitude of the location of the elevator 300 with the latitude / longitude of the lightning position 271 to determine either north-south or east-west.

  First, in the latitude direction, it is determined whether the lightning center position 271 is “north” or “south” of the location of the elevator 300. When the latitude of the lightning center position 271 is greater than the latitude of the location of the elevator 300, the lightning center position 271 is located "north" with respect to the elevator 300, and vice versa.

  Further, it is determined whether the center position 271 of the lightning is “east” or “west” of the location of the elevator 300. When the longitude of the lightning center position 271 is greater than the longitude of the location of the elevator 300, the lightning center position 271 is located “east” with respect to the elevator 300, and vice versa.

  In this case, the combination of the discrimination result of the latitude direction and the discrimination result of the longitude direction is combined, and any one of the east direction, the west direction, the south direction, the north direction, or the intermediate direction between the northeast direction, the northwest direction, the southeast direction, and the southwest direction. Is determined, and the result is used as a calculation result.

  Furthermore, as shown in FIG. 12, it is good also as the direction of a lightning in each azimuth | direction area | region which centered on the location (latitude, longitude) of the elevator 300, and divided the circumference | surroundings into 16 equally.

  Here, 360 ° around the elevator 300 is in the range of 22.5 ° centered on the east-west direction, the east region and the west region, and the south region is a range of 22.5 ° centered on the north-south direction, and North east region and west south west region, north east region and south west region, north north east region and south south west region, north north west region and south south east region, north west region and south east region Are divided into 16 azimuth regions, a west-northwest region and an east-southeast region. Then, it is determined in which of the 16 azimuth regions the lightning position 271 is approximately, and the determination result is set as the lightning direction.

Specifically, the output necessity determination unit 343 determines that Δx = (longitude of the lightning center position 271) − (longitude of the location of the elevator 300) and Δy = (latitude of the lightning center position 271−the location of the elevator 300). Of latitude). Then, based on the obtained gradient of (Δx, Δy) and the positive / negative of Δx, Δy, it is determined in which of the 16 orientation regions the lightning center position 271 is located. For example, at the position of latitude θ, the inclination α can be calculated by α = tan ⁻¹ (Δx × cos θ / Δy).

For example, as in the example of FIG. 7, the position of the lightning 271 is calculated as (36.047 ° north latitude, 140.024 ° east longitude), and the location of the elevator 300 is (35.991 ° north latitude). , East longitude 139.992 °), Δx is 0.032 ° and Δy is 0.056 °. As shown in FIG. 12, the inclination α, which is the direction of the lightning position 271 with respect to the elevator 300, is calculated by tan ⁻¹ (0.056 / (0.032 × 0.8)) and becomes 65.43 °. . Therefore, in this case, it is determined that the lightning center position 271 is in the east-northeast region with respect to the elevator 300.

  By calculating the direction of lightning in each time zone, the moving direction can also be grasped.

  Next, an example of a display screen displayed by the output data generated when the output necessity determination unit 343 determines that the output is necessary based on the surrounding information 350 will be described. FIG. 13 is an example of the display screen 380.

  As shown in the figure, the display screen 380 includes a warning display area 381, a thunder intensity display area 382, and a thundercloud movement display area 383.

  In the alert display area 381, information in which the alert content 372 of the alert information 370 is converted into a message is displayed. In the lightning intensity display area 382, the generation time zone 264 in the local time zone information 260a is displayed among the lightning information received as the surrounding information 350. In the thundercloud movement display area 383, activity map information 270a is displayed. As an example of the display screen 380, a lightning position 271 (not shown) may be illustrated in the display content of the thundercloud movement display area 383.

  In the thundercloud motion display area 383, each map of the activity map information 270a may be displayed at a predetermined time interval, for example, every 3 seconds, according to the order of time zones. Thereby, the movement of the lightning can be visually displayed.

  The output control unit 344 performs display or voice guidance from the in-car display 323 and the hall display 333 in accordance with an instruction from the output necessity determination unit 343.

  The elevator control device 310 has the same hardware configuration as that of the monitoring server 200. Each function of the elevator calculation unit 312 is realized by the CPU 291 expanding and executing a program stored in the storage device 293 or the like in the RAM 292 in advance. The server storage unit 230 is built in the storage device 293.

[Ambient environment information provision processing]
Next, the flow of the surrounding environment information provision process of the elevator by the monitoring server 200 and the elevator control device 310 will be described. FIG. 14 is a processing flow of the elevator ambient environment information providing process of the present embodiment. Here, a case where there is one monitoring target elevator 300 will be described as an example.

  In the monitoring server 200, the lightning information acquisition unit 221 acquires the lightning information 240 from the Web server 400 at predetermined time intervals (step S1101).

  Each time the lightning information 240 is acquired, it is stored in the server storage unit 230. Then, when the lightning information acquisition unit 221 stores the lightning information 240 in the server storage unit 230, the lightning information processing unit 222 processes the lightning information 240, and the local time zone information 260, the activity map information 270, and the lightning position 271. Is generated (step S1102).

  When the processed lightning information 250 is generated, the lightning information distribution unit 223 refers to the elevator information 280 and extracts the ambient information 350 to be transmitted for each monitored elevator 300 from the server storage unit 230 (step S1103). It transmits to the target elevator 300 (step S1104).

  When the surrounding information receiving unit 341 of the elevator control device 310 receives the surrounding information (step S1201), the surrounding information receiving unit 341 stores it in the elevator storage unit 313 (step S1201).

  When the new surrounding information 350 is stored in the elevator storage unit 313, the output necessity determination unit 343 first resets the current display contents of the car display 323 and the hall display 333 (step S1202).

  Next, it is determined whether or not the newly registered ambient information 350 is the pattern P0 (step S1203). The output necessity determination unit 343 refers to the lightning information 240a in the surrounding information 350, and determines which pattern 361 is based on the activity after 0-10 minutes and the activity after 10-70 minutes. To do.

  If the pattern 361 is P0, it is not necessary to output it, so the process is terminated, the process returns to step S1201, and the reception of surrounding information is awaited.

  On the other hand, when the pattern 361 is other than P0, that is, any one of P1 to P3, output data to be output to the hall display 333 is generated (step S1204). Here, the alert content 372 associated with the specified pattern 361 is extracted from the alert information 370, and the display screen 380, output audio data, and the like are generated using the extracted alert content 372.

  Then, the output controller 344 outputs all the halls from the hall display 333 (step S1205).

  Next, with reference to the determination result of the destination determination unit 342, it is determined whether or not a destination in the reference floor direction has been registered (step S1206).

  When the destination in the reference floor direction is registered, the output necessity determination unit 343 causes the output control unit 344 to output from the in-car display 323 (step S1207), ends the processing, returns to step S1201, and returns to the surrounding information. Wait for reception.

  On the other hand, if the destination in the reference floor direction is not registered in step S1206, the process ends as it is, and the process returns to step S1201 to wait for reception of surrounding information.

  As described above, in the present embodiment, as described above, the lightning information 240 is acquired from the Web server 400, and the lightning information 240 around the building where the elevator 300 is installed is monitored for each monitored elevator 300. Is extracted as surrounding information 350 and transmitted to the elevator 300, and the surrounding information 350 affects the traffic of the building, and the elevator 300 gives an instruction for traveling in the reference floor direction determined in advance. An elevator controller that outputs the surrounding information 350 and the alert information to the in-car display 323 in the car 320 when received.

  As described above, according to the present embodiment, information such as the lightning occurrence status and the direction of lightning movement is guided to the user of the elevator 300 who is going to the reference floor, which is the floor with the entrance to the outside of the building. it can. For this reason, effective information can be provided for the user of the elevator 300. For example, by obtaining this information, the elevator 300 user can avoid unnecessarily going out. Furthermore, since it is a motivation to avoid the use of the elevator 300 itself, it is possible to reduce the user from being trapped in the elevator by lightning.

  That is, according to the present embodiment, lightning information that is environmental information around the elevator 300 is effectively utilized, and convenience for the user is enhanced.

  Convenience is further enhanced by including information such as contact information when the elevator stops in the case of using the elevator 300 and preparations for lightning when going out in the alert information.

  In addition, by performing guidance according to the intensity of lightning, for example, with the development, approach, and passage of lightning, each elevator 300 moves in the time zone where lightning occurs, the direction in which lightning comes, and movement. You can grasp the direction.

  In addition, by displaying on the hall display 333 of the hall (stop) instructed to travel in the reference floor direction, information can be provided to the user at an earlier stage before the elevator 300 is used. As a result, confinement due to lightning can be further reduced, and convenience for the user is further enhanced.

  In the above-described embodiment, when the content of the surrounding information 350 needs to be output, the information is output from all the hall displays 333. However, the present invention is not limited to this. For example, the hall display 333 may be configured to output only when the hall button 332 instructs to travel in the reference floor direction. Further, it may be configured to output only the hall display 333 of the hall instructed to travel in the reference floor direction. Thereby, the output of the hall display 333 can be suppressed to a necessary and sufficient one.

  In this case, in the output necessity determination process, after determining the presence or absence of registration in the reference floor direction, output data is generated and displayed on the hall display 333 according to a predetermined criterion.

  Note that acquisition, processing, and selective distribution of lightning information may be performed by either the monitoring server 200 or the elevator 300.

  For example, in the above embodiment, the lightning position 271 is calculated by the monitoring server 200, but may be calculated by using the ambient information 350 in each elevator 300. For example, in the environmental information acquired by the monitoring server 200, when thunderclouds are generated at a plurality of discrete locations, it is more efficient to calculate the position of the surrounding lightning in each elevator 300.

  Further, for example, the monitoring server 200 may determine the contents of the surrounding information 350 and transmit the information to the elevator 300 only when there is the surrounding information 350 that needs to be displayed. Thereby, the communication amount between the monitoring server 200 and each elevator 300 can be reduced.

  In this case, for example, the pattern information 360 is held on the monitoring server 200 side, and the monitoring server 200 side determines whether or not the pattern of the surrounding information 350 is P0. And it transmits only in cases other than P0.

  Further, the lightning information 240 and the processed lightning information 250 of the entire range acquired on the monitoring server 200 side are transmitted to each elevator 300, and the elevator 300 extracts the surrounding information 350 that is the lightning information around itself. Also good. Thereby, the processing load in the monitoring server 200 can be reduced.

  Further, the lightning information 240 of the entire range acquired on the monitoring server 200 side may be transmitted to each elevator 300, the processed lightning information 250 may be generated on the elevator 300 side, and the necessary ambient information 350 may be extracted. Good.

  Further, in each elevator 300, lightning information may be acquired from the Web server 400 at predetermined time intervals, processed, and the surrounding information 350 may be extracted. Thereby, the processing load in the monitoring server 200 can be reduced, and the communication amount between the monitoring server 200 and the elevator 300 can also be reduced.

  In the above embodiment, the surrounding information is displayed on the car display 323 and the hall display 333 only when the traffic situation around the building where the elevator 300 is installed is affected. However, the lightning information 240 and the processed lightning information 250 may be displayed each time new ambient information 350 is received regardless of the situation.

  Further, when processing lightning information, the location (latitude, longitude) of the elevator 300 may be subjected to mathematical processing, and the location may be processed into a center position (latitude, longitude) for predicting the lightning activity. As a result, the number of elevators in the grid whose activity is predicted and their specifications can be grasped, and lightning strikes and the frequency of failure caused by it due to differences in specifications and buildings of the elevators in that grid are evaluated and analyzed. be able to.

  In the above embodiment, the case where the environmental information is lightning information among the weather information has been described as an example. However, the environmental information is not limited to this. For example, it may be weather information such as rain (precipitation), typhoon, and snow. Furthermore, traffic information may be used.

  In the case of traffic information, for example, traffic information on each route or road, accident information, and the like. In this case, the monitoring server 200 periodically obtains traffic information from the Web server 400 and provides route and road congestion information, accident information, and the like related to each elevator 300. Routes and roads provided for each elevator 300 are registered in advance in the elevator information 280.

  Further, the environment information processing is not limited to the above processing. The optimum processing is selected according to each environmental information. Further, even lightning information may be processed other than the above.

  Furthermore, the information provided to each elevator 300 may be plural types. For example, it may be a combination of lightning information and traffic information, lightning information, typhoon information, precipitation, and the like.

  Further, the elevator control device 310 may include an input operation unit so that the user can set and change the pattern information 360 and / or the alert information 370. As a result, it is possible to set according to the characteristics of the location of each elevator 300 and to call attention.

100: Ambient environment information providing system, 110: Network,
200: Monitoring server 210: Server communication unit 220: Server control unit 221: Lightning information acquisition unit 222: Lightning information processing unit 223: Lightning information distribution unit 230: Server storage unit
240: Lightning information, 240a: Lightning information, 240m: Observation mesh information, 241: Prediction date, 242: Center position information of observation mesh, 243: Activity, 244: Observation mesh number, 250: Processed lightning information, 260: Area Time zone information, 260a: Local time zone information, 261: Observation mesh number, 262: North latitude, 263: East longitude, 264: Occurrence time zone, 270: Activity level map information, 270a: Activity level map information, 271: Center position, 280: Elevator information, 281: Elevator ID, 282: Position information, 283: Observation mesh number, 291: CPU, 292: RAM, 293: Storage device, 294: Input / output I / F, 295: Communication I / F, 296 :bus,
300: Elevator, 310: Elevator control device, 311: Elevator communication unit, 312: Elevator operation unit, 313: Elevator storage unit, 320: Ride car, 322: In-car destination instruction button, 323: In-car display, 330: Hall Equipment, 332: Hall button, 333: Hall display, 341: Ambient information receiving unit, 342: Destination determining unit, 343: Output necessity determining unit, 344: Output control unit,
350: Ambient information, 360: Pattern information, 361: Pattern, 362: State, 363: Activity information, 370: Alert information, 372: Display content, 380: Display screen, 381: Alert display area, 382: Thunder intensity display area, 383: thundercloud movement display area,
400: Web server

Claims (9)

An elevator surrounding environment information providing method for providing an elevator user with environment information around a building where the elevator is installed,
Based on the location information of the elevator, the environmental information around the building where the elevator is installed is extracted as ambient information from the environmental information acquired via the communication device and transmitted to the elevator. ,
When the surrounding information affects traffic around the building and receives an instruction for traveling in a predetermined reference floor direction, the surrounding information and the alert information are output to the display in the car A method of providing information on the surrounding environment of an elevator characterized by this. An elevator ambient environment information providing method according to claim 1,
The environmental information is meteorological information from the present to a predetermined future time, in units of a predetermined observation mesh, updated at predetermined time intervals,
The surrounding information is the environment information within an observation range composed of a plurality of the observation meshes centered on the observation mesh including the position specified by the position information of the elevator,
When the surrounding information includes a sign of a predetermined natural disaster, it is determined that traffic around the building is affected. An elevator surrounding environment information providing method according to claim 2,
The method for providing information on the surrounding environment of an elevator, characterized in that the sign of the natural disaster is lightning. An elevator ambient environment information providing method according to claim 3,
The method for providing information on the surrounding environment of an elevator, wherein the alert information that differs depending on the intensity of lightning is output. An elevator ambient environment information providing method according to claim 1,
The method for providing information on the surrounding environment of an elevator, wherein when an instruction to travel to the reference floor is instructed by a destination instruction button in a car, it is determined that an instruction to travel toward the reference floor is received. An elevator ambient environment information providing method according to claim 1,
The elevator surrounding environment information providing method, wherein an instruction for traveling in the direction of the reference floor is made by a hall button. An elevator environment information providing method according to claim 6,
The method for providing information on the surrounding environment of an elevator, wherein the surrounding information is further output to a display of a hall instructed to travel in the reference floor direction. An elevator ambient environment information providing method according to claim 1,
The environmental information is a predetermined range of traffic information including the position specified by the position information of the elevator,
The surrounding environment information providing method for an elevator, characterized in that the surrounding information is predetermined route and traffic congestion information. An elevator surrounding environment information providing system for providing an elevator user with environmental information that affects traffic around a building where the elevator is installed,
A monitoring server that acquires environmental information, extracts the environmental information around the building where the elevator is installed, and transmits the environmental information to the elevator for each monitored elevator;
When the surrounding information affects the traffic of the building and an instruction for traveling in a predetermined reference floor direction is received, the elevator control device outputs the surrounding information and the alert information to the display in the car An elevator environment information providing system characterized by comprising: