KR20190028631A - Elevator simulator - Google Patents

Abstract

The present invention is to more accurately evaluate the influence on a user relating to a specification about an elevator facility and the influence relating to user′s behavior. A user is generated on a simulation such that the user takes an action corresponding to elevator information set in connection with an elevator facility by an elevator facility setting part and building information set in connection with the whole building by a building information setting part. Under this condition, the simulation is executed. Accordingly, the influence on a user relating to a specification of the elevator facility and the influence relating to user′s behavior can be evaluated more accurately.

Description

[0001] ELEVATOR SIMULATOR [0002]

The present invention relates to an elevator simulator, and more particularly to an elevator simulator which performs simulations according to an elevator installation.

The conventional elevator simulator is a case where the recommended object is applied to the recommended object building facility based on the recommended candidate extracted under a predetermined condition, the operation history data of the recommended object building facility, the building facility status data, and the building facility parameter option data , And outputs a recommendation candidate as necessary (see Patent Document 1).

Japanese Patent Application Laid-Open No. H02-226460

However, in the conventional elevator simulator, even if the influence of the installation of the building equipment itself could be evaluated, the influence on the user about the specification of the elevator equipment and the influence on the behavior of the user could not be evaluated. Therefore, it was necessary to thoroughly examine the installation plan of the building equipment, and it took a long time to plan the installation of the building equipment. On the other hand, in the case of insufficient review in the planning of the installation of the building equipment, the usability of the user deteriorates, and if it is intended to cover this, a cover in the operation side is required such as guiding the security guards in the building, There is a possibility that the unnecessary labor costs will be extra.

The present invention has been made in view of the above points, and it is an object of the present invention to provide an elevator simulator capable of more accurately evaluating not only the effect of installation of a building facility but also the influence on the user about the specification of the elevator equipment and the influence on the behavior of the user .

In order to solve these problems, in the present invention, there is provided an elevator system including an elevator facility setting unit for setting elevator information about an elevator equipment, a building information setting unit for setting building information on building specifications of the entire building, A user setting section for setting user information including a generation time, a generation layer, a destination layer and an attribute of a user to be generated simulatively; an in-building user control section for controlling the behavior of the user; An elevator control unit for managing the elevator control unit, an input device for making a service request to the elevator control unit from the in-building user control unit, and a platform output device for outputting a result of the service request, The elevator information and the building information The simulation is performed while simulating the user to take action according to the beam.

According to the present invention, not only the influence of the installation of the building equipment but also the influence of the change of the behavior of the user in accordance with the specification of the building equipment can be evaluated more accurately.

1 is a system configuration diagram of an elevator simulator according to the present embodiment.
2 is a flowchart for explaining an example of a user generating process according to the present embodiment.
3 is a flowchart for explaining an example of registration determination processing according to the present embodiment.
4 is a flowchart for explaining an example of the device registration process according to the present embodiment.
5 is a flowchart for explaining an example of the device user waiting process shown in Fig.
6 is a flowchart for explaining an example of a destination layer registration process shown in Fig.
FIG. 7 is a flowchart for explaining an example of the assigned breath waiting process shown in FIG. 6;
8 is a flowchart for explaining an example of the user updating process shown in Fig.
Fig. 9 is a flowchart for explaining an example of the landing gear walking process shown in Fig. 8;
10 is a flowchart for explaining an example of the gait determination processing shown in Fig.
11 is a flowchart for explaining an example of the hall waiting process shown in Fig.
12 is a flowchart for explaining an example of the alignment wait process according to the present embodiment.
Fig. 13 is a layout diagram for simulating gate interlocking specifications according to the present embodiment. Fig.
Fig. 14 is a layout diagram of a gate interlocking specification according to the present embodiment at the time of simulation. Fig.
Fig. 15 is a layout diagram at the time of simulation of the gate interlocking specification according to the present embodiment. Fig.
Fig. 16 is a layout diagram of a hall lantern lighting specification of a vertical landing gear button specification according to the present embodiment during simulation. Fig.
Fig. 17 is a layout diagram of the hall lantern boiling light specification of the vertical landing gear button specification according to the present embodiment. Fig.
Fig. 18 is a layout diagram of a wheelchair specification simulation according to the embodiment of the present invention; Fig.
Fig. 19 is a layout diagram for simulation of a wheelchair specification of a vertical type landing gear button specification according to the present embodiment; Fig.

Hereinafter, one embodiment of the present invention will be described in detail with reference to the drawings.

(1) System configuration

Fig. 1 shows a schematic configuration example of a simulation system 100 according to the present embodiment.

The simulation system 100 includes a user setting unit 1, a building information setting unit 2, an elevator facility setting unit 3, an elevator specification setting unit 4, a time zone setting unit 5, and a simulation unit 10 . The simulation unit 10 includes an in-building user control unit 11, an input device 12, an elevator group management control unit 13, an elevator control unit 14, a platform output unit 15, an elevator 16, (17).

The user setting unit 1 has a function of setting information about the user. The information about the user includes, for example, a generation layer for setting a floor on which a user enters the elevator hall, a destination floor indicating a destination floor set with use of the elevator, a general user, a wheelchair user, or a VIP user A walking speed of a user walking in a hole, a generation distribution for setting a generation rate of a user for each generation layer or a target layer, and the like.

The building information setting unit 2 has a function of setting building information. The building information includes, for example, the number of floors of a building and the distance between floors. The building information includes information such as the number of reanimation persons indicating how many users are present in each office of each floor of the building, building specifications in each floor, lobby floor, parking lot floor and public floor.

The elevator equipment setting unit 3 has a function of setting the elevator information concerning the elevator equipment. As an example of this elevator facility, there are a boarding car (hereinafter, simply referred to as " car ") having six cars installed, an installation position in the floor of the elevator car, and a destination floor registering device A gate interlocking facility capable of registering a destination layer when a gate provided at the entrance of the landing station passes, and an elevator arrival / And a hall lantern for guiding the reservation and reservation directions when another elevator of the direction guidance of the city is reserved. When the destination floor is registered in the platform, the destination floor stop layer To be set in which position on the floor.

The elevator specification setting unit 4 has a function of setting the specifications of the elevator equipment installed. Examples of the specifications of the elevator equipment include the speed of the elevator, the width of the door, and the number of the elevators. The operation specifications of the elevator facility include the presence or absence of the reservation function immediately after turning on the elevator lantern of the unit determined according to the service request at the moment of issuing the service request from the landing button.

The time zone setting unit 5 has a function of setting a time zone in which the simulation is performed. Generally, the elevator operation situation in the building is different every time zone. For example, in the office hours, there are many cases in which a user flows into a building, and as a user's movement, a re-enactment layer of each user is used as a target layer from the lobby layer. In the first half of the lunch time period, when there is a floor where there is a restaurant floor or a restaurant in a building, the number of users who move from the floor of each user to a floor where a restaurant floor or a restaurant exists is increased. There are a large number of users who move from the re-entry level to the lobby level of each user, as opposed to the work-out time zone, in the exit time zone.

The generation distribution for setting the generation rate of the user in each of the generation layers and the target layers in the time zone setting section 5 and the user setting section 1 is set to be related to each other. Here, as a method for setting the occurrence rate of the user, a method of automatically setting the occurrence rate when the time zone is set, a method of setting the occurrence distribution of the user sequentially at an arbitrary time zone, a generation distribution Or a method of determining the generation distribution for each time zone based on the past measurement data of the similar building specification may be employed.

In the method of automatically setting the generation rate when the time zone is set, for example, when the time zone is set as the operation time zone, the occurrence rate of the user from the lobby floor to each floor is set according to the number of people to be reattached to each floor. Specifically, when the occurrence rate of the user going from the lobby floor to each floor is set to 40% in the 30 minutes of the office hours 8:15 to 8:45, the number of the re-occupants on the 5th floor is 100, When the re-entry number of the floor was 80, there were 40 users going from the lobby floor to the fifth floor, and 32 users going to the fourth floor.

In the method of sequentially setting the generation distribution of the user at an arbitrary time slot, the generation rate of the user for each of the generation layer and the target layer is set for each time slot. Concretely, the generation rate of the user from the lobby floor toward the other floor is 15% between 8:15 and 8:30, and between the lobby floor and the other floor in the time zone between 8:30 and 8:45 The occurrence rate of the user is set to 25%. Further, the width of the time zone can be set arbitrarily, and the set value of the occurrence distribution can also be set as a ratio, or may be set for each floor in detail.

In such a setting method, for example, 200 users are generated from the lobby floor, 80 users are in the 10th and 4th floors, 130 guests are in the 5th floor, More specifically, 125 users from the lobby floor to the fifth floor, 75 users from the lobby floor to the fourth floor, 5 users from the first floor to the fourth floor, and the users from the first floor to the fifth floor are 5 May be set in detail.

In the method of determining the generation distribution every time zone according to the use of the building, in the method of automatically setting the generation ratio when the above-mentioned time zone is set, the set value is changed according to the building use. Examples of the building use include an office building, a high-rise house (condominium), a hotel, or a jigger building. For example, in the office building, the flow of the user from the lobby floor toward each floor is common. However, in a high-rise house (condominium), the flow of users from each floor toward the lobby floor increases. In addition, since the time zone is also different from the office building, the time zone and the occurrence distribution also vary depending on the use of the building.

Once these information settings are completed, the simulation becomes feasible. The simulation unit 10 for executing the simulation always updates the system time, and for the simulation described later, the in-building user control unit 11 for controlling the floor movement of the user and the elevation to the elevator 16, An elevator group management control unit 13 for carrying out the management of operations in accordance with the service request, and an elevator group management unit 13 for receiving a service request from the elevator group management control unit 13 An elevator control unit 14 for controlling an elevator car or opening and closing of a door in response to a service request, a landing area output device 15 for guiding the user from the elevator group management control unit 13 or the elevator control unit 14, And an elevator 16 in which the user ascends and descends. In the present embodiment, the term " user " indicates a user who is generated in a simulation.

The elevator group management control unit 13 finally outputs the evaluation in the simulation condition set by the comprehensive evaluation output unit 17 on the occasion that the system time of the simulation unit 10 reaches the simulation end time. In this evaluation, the elevator waiting time until arriving at the platform of each user output from the in-building user control unit 11 until getting on the elevator, the time of riding from the elevator to the time of getting off, And the time of completion of the service until the destination reaches the destination floor. In addition, in the evaluation, for example, when an elevator waiting time of 60 seconds or more is defined as a long waiting time, a long-term waiting is performed as an index indicating how many persons of the user having a long waiting time exist for the total number of users Or the maximum number of waiting persons indicating the maximum number of users waiting in the elevator at the landing stage during the simulation time is output.

The elevator group management control unit 13 calculates the time taken until the boarding car of each elevator 16 arrives on the entered floor based on the input time of each of the input devices 12, The evaluation of the average time, the maximum time, and the minimum time during the simulation time such as the time taken from the arrival of the destination floor to the arrival at the destination position, the number input by the input device 12, do.

The evaluation output from the elevator group management control unit 13 is output from the elevator control unit 14 when it is not the group management specification or when only one elevator is simulated.

The in-building user control unit 11 performs an operation and a time management according to the apparatus to specifically reproduce the movement of the user on the platform from the generation of the user. The elevator output situation changes in accordance with the equipment and the specifications set by the elevator setting unit 3 and the elevator specification setting unit 4 so that their movements change according to the output state. Their movement will be described later (see Figs. 2 to 12).

The input device 12 corresponds to, for example, a vertical landing platform button and a landing destination floor registration device. The position of the input device 12 in the landing area can be set to any coordinates in accordance with the landing layout. In the input device 12, data necessary for input are different for each device to be targeted, but data included in the user information are all input thereto.

For example, when the input device 12 is an up / down type landing pad button, the input information by the input device 12 is data indicating whether the service request is from the landing floor to the upper floor or the lower floor Therefore, based on the user information, the generated layer information, and the destination layer information, it is determined whether the service request to the upper layer or the lower layer is required for each user. The input information is stored in the shared memory shared between the in-building user control unit 11 and the input device 12 in the simulation unit 10. [

In the case of the specification using the destination layer registration device or the gateway interworking specification, the input layer information and the user attribute of the user are input information, not the input information of the direction of the upper layer or the lower layer. This input information is stored in the shared memory installed in the simulation unit 10. [ Compared to the case of the up / down type landing station button, the amount of information is increased. When the equipment is determined by the elevator facility setting unit 3, the data size corresponding to the input information by each input device 12 is secured in the shared memory .

The elevator group management control unit 13 automatically sets the group management specifications based on the setting information by the building information setting unit 2, the elevator facility setting unit 3, and the elevator specification setting unit 4. [ The elevator group management control unit 13 aims at minimizing the waiting time when selecting the best elevator for the input device 12 such as the number of elevators and the elevator speed in addition to the setting of the inter-floor distance A parameter used for actual control such as a parameter necessary for calculation of the arrival forecast time is automatically extracted from each setting information and set.

The elevator group management control unit 13 manages the operation of the elevator according to each specification. For example, when the upper and lower type elevation button of the wheelchair specification is installed as the input device 12, the elevator group management control unit 13 controls only the elevator close to the elevation type elevation button to be the assigned number. When the elevator button of the VIP specification is provided as the input device 12, for example, the elevator group management control unit 13 regards a specific unit as a VIP unit, and responds to a new service request for the VIP unit . On the other hand, when the destination layer registration device is provided as the input device 12, the elevator group management control section 13 controls the number of the stop layers along the destination layer to be suppressed because the destination layer can be known from the landing area. Thereby, it is possible to carry out an operation with an increased transport capacity.

In addition, the elevator group management control unit 13 can be controlled according to a preset elevator specification. The elevator group management control unit 13 controls the lighting state of the hall lantern as the landing platform 15, for example, depending on whether the hall lantern is immediately lit or not, Off state or the blinking state.

The elevator control unit 14 mainly performs control of the elevator alone, and controls door open / close control, elevator stop, start, acceleration, deceleration, and travel processing. The elevator specification is automatically set based on the information set by the elevator specification setting section 4, as in the case of the elevator group management control section 13. [ For example, parameters related to the above-described control such as the setting of the distance between the floors or the elevator speed are automatically set.

The elevator 16 is a general term for a facility including a boarding car on which the user ascends and descends, and the door open / close state, the car state, and the like are changed in response to an instruction from the elevator control unit 14. [ The elevator 16 is also associated with a destination floor reservation system for managing the registration of the destination floor.

In the comprehensive evaluation output section 17, the simulation results are summarized and outputted. The simulation results include information output from the in-building user control section 11, for example, elevator information, waiting time until each user arrives at the platform and rides in the elevator, And a service completion time from when the user arrives at the platform to when the user reaches the destination floor. In the present embodiment, an elevator waiting time of 60 seconds or more is defined as a long waiting time. The comprehensive evaluation output unit 17 outputs a probability (long-term waiting rate) indicating how much the number of users of a long waiting time exists for the number of users generated as a whole, for example, And outputs the maximum number of waiting persons indicating the maximum number of users waiting in the elevator.

Further, the comprehensive evaluation output unit 17 calculates the time taken for each elevator 16 to be serviced from the input time by each input device 12 to the destination floor registered by the input, the purpose of the elevator 16 A maximum time and a minimum time during the simulation time such as the time taken from arrival of the floor input to the destination position and the number of inputs of the input device 12 are output.

In addition, the comprehensive evaluation output unit 17 outputs, to the user's waiting area such as the time required for registration for each user in the time zone in which the simulation is performed for each building information, the time spent for extra movement, the waiting time at the platform, Or the number of people with respect to the air such as the maximum number of people waiting for registration at the time of registration and the maximum number of people waiting at the landing, such as the time for the user's atmosphere, may be evaluated and output.

(2) Simulation example

Fig. 2 shows an example of the procedure of the user generating process. This processing is executed by the in-building user control unit 11. [ In this processing, a user on the simulation is generated in accordance with the system time updated by the simulation unit 10. [

In step S1, the in-building user control unit 11 compares the system time with the occurrence time of the user. The in-building user control unit 11 executes a user generating process (step S2), which will be described later, when the system time coincides with the occurrence time of the user, and when the system time is inconsistent with the user's time, S3.

Here, the occurrence time of the user is set based on the user data created in advance by the user setting unit 1. [ The user data includes items such as an occurrence time, a user attribute, a walking time, a generation floor, a generation place, a destination floor, or a destination place, and these items are created for simulating the number of people to be simulated.

In step S3, the in-building user control unit 11 determines whether or not the user has arrived at the hall (platform). If the user does not arrive at the hall, the user generating process is terminated. The landing party user generating process is executed (step S4). In this platform user generating process, the in-building user control unit 11 simulates a user at the platform.

Fig. 3 shows an example of the procedure of the registration determination process. This processing is executed by the in-building user control unit 11. [ In step S11, the in-building user control unit 11 determines whether or not the specification of the elevator equipment is a gate interlocking specification. When the specification of the elevator equipment is the gate interlocking specification, the in-building user control unit 11 performs a device registration process (to be described later) (step S14). If the elevator equipment specification is not the gate interlocking specification, the in-building user control unit 11 executes step S12.

In step S12, the in-building user control section 11 determines whether or not the destination floor registration apparatus is installed. When the destination floor registration device is installed, the device user waiting process to be described later is performed (step S15). If the destination floor registration device is not installed, the following step S13 is executed.

In step S13, the in-building user control unit 11 determines whether or not the specification of the elevator equipment is a specification (hereinafter, also referred to as " upper and lower type landing gear button specification " When the specification of the elevator equipment is the specification of the landing gear button of the upper and lower type, a landing button registration processing to be described later is executed (step S16).

Specifically, the in-building user control section 11 determines whether or not the response of the up / down button provided on the elevator platform of the generation layer is turned on (step S13). In the case where the response or the like is not turned on, the in-building user control section 11 regards that the upward button is pressed as an upward service request when the object layer is the upper layer than the generation layer, When the destination layer is the downward layer, it is assumed that the downward button is pressed as a downward service request. When the registration of the destination layer is completed, a hall waiting process (see Fig. 11) to be described later is executed.

Fig. 4 shows an example of the procedure of the device registration process shown in Fig. This processing is executed by the in-building user control unit 11. [ In step S21, the in-building user control unit 11 determines whether or not an available device exists. In the present embodiment, for example, a user data table (not shown) is prepared and if there is a user using the apparatus, the in-building user control unit 11 registers the user data corresponding to the user in the user data table do.

When the user data is registered in the user data table, it indicates that the user is using a device corresponding to the user data and the device is not empty. On the other hand, when the user data is not registered in the user data table, it indicates that the apparatus can be used. If there is an available device, destination layer registration processing is performed (step S24). On the other hand, if there is no available device, the following step S22 is executed.

In step S22, the in-building user control unit 11 selects a device with the smallest alignment. It is assumed that the above-described user data table is provided for each device. In the case where the user data is registered in the user data table, it is recognized that the device is not currently available and can not be used. However, in order to simulate the alignment, The internal user control unit 11 selects a user data table having a small number of registered data and registers user data. That is, it indicates that the user is aligned in front of the device with the smallest number of arrangements. The in-building user control unit 11 selects, for example, a device having a smaller device ID from Unit 1 to Unit 6 in the case of the same number of users. When the selection is completed in this way, the following step S23 is executed.

In step S23, the in-building user control unit 11 adds +1 to the number of waiting users. This makes it possible to clarify the number of users in the waiting queue. When the above process is completed, the in-building user control unit 11 performs the following device user wait process (step S25).

Fig. 5 shows an example of the device user waiting process shown in Fig. This processing is executed by the in-building user control unit 11. [ In step S31, the in-building user control unit 11 determines whether or not the user himself / herself is the zeroth orderer. This indicates that the user determines whether or not the user is at the head of the apparatus. When the user is at the forefront, the apparatus can be permitted, that is, for example, in the case of the gate interlocking specification, the gate can be operated, while in the case of the destination layer registration apparatus specification, the destination layer can be input.

The building user control unit 11 refers to the user data table (table "NO") to determine whether the user is the first or not. If the user is the 0th, the in-building user control unit 11 executes the destination floor registration process (see Fig. 6) to be described later (step S33). When the in-building user control unit 11 completes the destination floor registration process, it updates n (step S36). On the other hand, when the user is not the 0th user, the in-building user control unit 11 executes the following step S32.

In step S32, the in-building user control unit 11 determines whether or not the (n-1) th user exists. In the user data table, assuming that the first user is a user of n = 0, when n is updated, the (n-1) th user indicates a user who is in front of the user who is sorting. n = 1 indicates data of a user arranged next to the head, and the (n-1) th user indicates that the data is the first user.

When the registration of the user is completed in the above destination floor registration processing (step S33), and there is no user from the front of the apparatus, naturally there is no head user. If this is simulated, it means that there is no n-1th user because n = 0th user data is 0 or NULL in the user data table. When the (n-1) -th user exists, the following step S34 is executed. When the (n-1) -th user does not exist, the step S35 described later is executed.

In this step S34, the waiting process is executed. Since there is a user who is sorting, that is, there is a user in front of the user, nothing is done as an operation, but only the update of the user data table (table "NO") is performed. When such processing is completed, step S37 described later is executed.

In step S35, the (n-1) -th user is updated to the n-th user. This corresponds to the operation in which the user next narrows the column when the user in front of the user is absent in a situation where the users are aligned with each other. On the user data table, the empty n-1th user data is overwritten using the nth user data. Thereafter, the n-th user data is set to 0 or NULL, thereby making it possible to simulate the situation in which the users are aligned. When the update is completed, step S36 is executed.

In step S36, n is updated by +1. For example, in the case of n-1, the updating operation is performed by setting the value to n-2. When such an update operation is completed, the following step S37 is executed.

In this step S37, it is determined whether n is equal to or greater than the number of waiting users. If the conditions are matched, the process is terminated. If the conditions are not matched, it means that there is a user who is waiting for the user. Therefore, step S31 is executed.

Fig. 6 shows an example of destination layer registration processing shown in Fig. This processing is executed by the in-building user control unit 11. [ In step S41, the user attribute information and the destination layer information are registered using the input device 12. Usually, the information of the user is related to the ID held by the card placed on the gate. When the gate is interlocked, the destination layer of the user is transmitted from the security system side of the gate to the destination floor reservation system on the elevator side in addition to the user information such as general user, wheelchair user, or VIP.

However, in this simulation, in order to simplify the processing, it is assumed that the user data has user information and destination layer information for each user in advance. Necessary information is input to the input device 12. [ Necessary information is stored on the shared memory held by the input device 12. [ After that, the registration of the service request to the elevator side is completed. When the above input is completed, step S42 is executed.

In step S42, it is determined whether or not the assigned breath information is given. After the gateway interlocking specification, the destination floor registering device specification, and the input information are inputted, the service unit is determined based on the input information from the elevator side. The determined service unit is allocated and the exhalation information is transmitted.

Simulation is performed to simulate guidance to the user from the destination floor reservation system on the elevator side by storing necessary information on the shared memory held by the landing station output device 15. [ The in-building user control unit 11 determines whether or not the assigned breath is given (step S42).

When the assigned call is given, a user update process (see FIG. 8) to be described later is performed (step S43). When the user updating process is completed, the destination layer registration process is terminated.

On the other hand, when the assigned breath is not given, the assigned breath waiting process (see FIG. 7) to be described later is performed (step S44). When the allocation waiting processing is completed, the destination layer registration processing is terminated.

Fig. 7 shows an example of the assigned breath waiting process shown in Fig. This processing is executed by the in-building user control unit 11. [ In step S51, it is determined whether or not a predetermined time has elapsed. Here, in the case of the destination floor reservation system on the normal elevator side, although the destination floor registration apparatus has entered the destination floor after the input processing or the input processing at the gate interlocking is performed, Is not assigned to the user, or when an abnormal display is made, the user attempts to execute the input process again using the registration device. Therefore, the user waits until data is output after inputting. The predetermined time already described can be arbitrarily determined, and is usually set to about 3 seconds. If the predetermined time has elapsed, the step S52 is executed. If the predetermined time has not elapsed, the standby state is terminated.

In this step S52, re-registration processing is performed. Here, similarly to the step S41 in Fig. 6, necessary information is stored on the shared memory held by the input device 12. Fig. When the storage of the necessary information is completed, the re-registration process ends.

Fig. 8 shows an example of the user updating process shown in Fig. This processing is executed by the in-building user control unit 11. [ In step S61, the in-building user control unit 11 stores the assigned exhalation information output by the landing area output device 15 as user data. Since the allocated exhalation information is used in the elevator riding process of the user, the data configuration is prepared so that the assigned exhalation information can be retained for each user.

In step S62, the in-building user control unit 11 deletes the 0th user information. Here, the deletion is not the user information itself, but a user data table created for each device, for example, to simulate alignment. This is because, if the assigned breath is given after the registration of the apparatus is performed, the user does not align in front of the apparatus because the user is walking toward the assigned breath. To simulate this operation, the 0th user information is deleted from the user data table for sorting.

In step S63, the in-building user control unit 11 updates the registration completion time with the current system time. The in-building user control unit 11 can calculate the registration time by subtracting the occurrence time from the registration completion time using this time in the comprehensive evaluation described later. Thereafter, the following platform walking process (see Fig. 9) is performed (step S64).

Fig. 9 shows an example of the landing gear walking process shown in Fig. 8, and Fig. 10 shows an example of the running determining process shown in Fig. These processes are executed by the in-building user control unit 11.

In step S71 of FIG. 9, the in-building user control unit 11 obtains the distance L _H from the registered distance to the landing area. As the distance information, a distance from each unit is set at a point in time when the apparatus is set in advance. At the time when the assignment call is determined, the previously set distance information is acquired. For example, when the layout of the landing gear is set, the distance L _H is calculated from the coordinate position of the center of the apparatus and the coordinate position of the center position of each unit. That is, the distance L _H is automatically calculated at the time point set by the elevator installation setting section 3. [ The in-building user control unit 11 includes the distance information set as described above in the user information based on the assigned breath information.

In step S72, the in-building user control unit 11 obtains the walking distance in system time unit from the walking speed. When the system time is in units of 100 ms, the distance that the average user is walking in units of 100 ms is calculated in units of meters.

In step S73, a walk determining process (see Fig. 10) is performed. In this step S73, the in-building user control unit 11 determines whether there is a space that the user can walk. The determination as to whether or not there is a space that can be walked is considered as follows.

As the first determination method, for example, depending on the layout and size of the building set by the building information setting unit 2 and the elevator facility setting unit 3, the maximum number of waiting users in the landing area and the number of users waiting in the waiting area It is possible to illustrate that the number is automatically set. In the present embodiment, it is determined that there is no space when the maximum user waiting number and the actual waiting user waiting number are the same value.

As the second determination method, a method of simulating the moving situation of the user may be employed. In this method, the occupation size is determined for each user, the shortest movement route from each user's position to each unit is calculated, and movement of each user is started in accordance with the movement route. In the simulation, each user moves on the movement path for the above-described walking distance in accordance with the update of the system time. Another user is staying in front of the user's eyes or an obstacle is present. Instead, a method may be used in which a determination is made as to whether there is an occupied size space of the user on another moving route. When the space is present, the step S82 is executed, while when the space does not exist, the step S85 is executed.

In this step S82, it is determined whether there is space available for the user to walk in the walking direction of the user. For example, assuming that a plurality of users are standing by in an elevator near a platform entrance, when another user is staying in front of the elevator in front of the user, There may be a case where it is possible to arrive in front of the above elevator by detouring instead of moving in. As described above, when another user is not staying in front of the user's eyes, it is determined that there is a space in the walking direction of the user, and the user can go straight ahead. If another user is staying in front of the user's eyes, it is determined that there is no space in the user's walking direction, and step S83 is executed. Alternatively, for example, a method may be employed in which it is determined that the organism can not go straight when the number of people waiting in the elevator near the entrance to the platform exceeds a predetermined threshold value, and a determination is made that there is no space in the user's walking direction .

In step S83, the in-building user control unit 11 adds a distance for extra walking to the distance L _H from the registered distance to the landing site. The distance to walk an extra is the distance to the detour described above. We calculate distance of user in front of the eye by the number of waiting people X occupation size and the size above threshold, and take the distance as extra walking distance.

In step S84, the in-building user control unit 11 adds penalty 1 and penalty 2, multiplied by the walking speed with respect to the extra walking distance. As a result, the extra time taken by the user can be applied as penalty 1 to each user. Thereafter, the walking determination processing is terminated.

On the other hand, the above-described step S85 is a case where it is determined that there is no space for the user to walk on in step S81, and therefore, the user is in a state where the user is staying. In this step S85, the in-building user control unit 11 adds the staying time as penalty 2. In addition, the in-building user control unit 11 calculates the system time x walking distance as penalty 1 and adds the system time and the walking distance. Thus, as described later, it is possible to evaluate the user's staying time in the landing area. Thereafter, the walking determination processing is terminated.

Upon completion of the above-described gait determining process, the building user control unit 11 calculates the moving distance L _psn of the user from the equation ((system time-registration time) x walking time) - penalty 1. [

In step S75, the in-building user control unit 11 _compares the moving distance L _psn of the user with the distance L _H from the registered distance to the landing position, and determines whether or not the user has arrived at the destination. If both distances are the same, the in-building user control unit 11 determines that it has arrived at the destination, executes hall waiting processing (see Fig. 11) described later (step S76), and then executes step S77. On the other hand, when both distances are not the same, the landing pad walking process is ended.

In the above-described step S77, as the user data, the hole arrival time is updated. The hall arrival time can be evaluated by storing the current system time as it is, and subtracting the occurrence time later from the hole arrival time. Thus, the landing platform walking process is finished.

Fig. 11 shows an example of the hall waiting process shown in Fig. This processing is executed by the in-building user control unit 11. [ In step S91, it is determined whether there is a service layer indication. It is determined whether or not it is set by the elevator specification setting section 4. [ For example, in a case where a so-called bank division is performed in a high-level and a low-level in a single bank in an elevator installation, the user selects any one of the banks capable of providing service to a desired destination floor in the landing platform. Therefore, the display of the service floor by signboard or sign display is specified on the platform, and the user selects either one of the banks to be used with reference to such information. If there is a service layer indication, step S92 is executed. If there is no service layer indication, step S93 is executed.

In step S92, the target unit capable of serving the destination layer desired by the user is selected. For example, if the user has five floors among the first floor to the sixteenth floor and the elevator equipments includes six subject booths, the first floor to the third floor have the first to eight floors as the service floor When it is assumed that the service units of the units 4 to 6 are the service layers of the 9th to 16th floors, the target customer's units are the first to third units. When the selection of the target machine is completed, the following step S93 is executed. In the present embodiment, the assigned target unit is also referred to as " assigned unit. &Quot;

In this step S93, it is confirmed whether or not the assigned breath is given. When the assignment call is given, the following step S94 is executed. When the assignment call is not given, the step S97 to be described later is executed.

In this step S94, it is determined whether or not the hall lantern or the stop floor display lamp of the target unit is turned on. In this simulation, it is determined from the information on the shared memory held by the landing platform 15. The destination floor reservation system on the elevator side in the state in which the assignment call is given determines whether or not the destination floor can be normally registered according to the situation of the landing platform output device 15. [ For example, if the fifth layer is registered as the target layer, for example, if another layer is displayed, or if nothing is displayed, re-registration is required.

Considering precisely simulating the setting error of the control parameters of the elevator, for example, when the user intends to ride but the door of the elevator is closed before the riding, the hall lantern and the stop floor lamp are turned off and re-registration is required . Therefore, when the hall lantern or the stopper layer indicator lamp of the target apparatus is turned on, the user waits for alignment in front of the target apparatus (step S95) and terminates the hall waiting process. When the hall lantern of the target machine or the stop layer indicator is turned off, the destination floor registration processing is executed (step S96). The destination floor registration process here is, for example, a destination floor registration device installed on a platform.

In the above-described step S97, it is determined whether or not the hall lantern in the target air conditioner is turned on. In the present simulation, it is determined based on the information on the shared memory held by the landing platform 15. In the above-described example in which the upper and lower button specifications are assumed, it is determined whether or not the hall lantern in the units 1 to 3 is turned on. When the hall lantern is lit, the user waits for alignment in front of the target radiator indicated by lighting of the hall lantern (step S98). On the other hand, when the hall lantern is turned off, the following step S99 is executed.

In this step S99, it is determined whether or not the response of the up and down button of the target bank is turned on. In this simulation, it is determined from the virtual memory held by the landing gear output device 15. [ In the case of the Up and Down button specifications, when one button is pressed (registered), all associated buttons are turned on. Therefore, it is possible to judge whether or not the service request from the landing ground is inputted by judging whether the hall lantern is lit or not.

On the other hand, although the hall lantern is turned off, when the landing pad button is continuously lit, there is no reservation function immediately, so that the alignment position becomes the center of the landing pad so that the user can be aligned regardless of which elevator arrives. When the hall lantern is lit, the user waits for alignment at the center position of the landing platform (step S100). On the other hand, when the hall lantern is off, re-registration processing of the landing up / down button is performed (step S101). The content of the re-registration processing of the landing up / down button is the same as that of step S16 already described. Thus, the landing waiting process is completed.

12 shows an example of the alignment wait process. This processing is executed by the in-building user control unit 11. [ In step S111, it is determined whether or not the hall lantern in the subject direction of the target expiration unit is blinking. For example, in the case where the user is targeting Unit 1, the moving direction is the upward direction when the generation layer as the platform is four layers and the destination layer is nine layers. Therefore, when the first unit arrives, the door in the upward direction is not opened and the lantern is blinking. Here, when the second unit arrives, and when the hall lantern flickers downward of the first unit, it does not become an object. If the hall lantern in the target direction of the target airplane is blinking, the following step S112 is executed. If the hall lantern in the target direction of the target airplane is not blinking, step S113 described later is executed.

In this step S112, since the arrival of the elevator is indicated by the flickering of the hall lantern, the user of the landing area aligns the hall lantern in front of the flickering burner or narrows the distance from the previous user.

In the above-described step S113, it is determined whether or not the target air-conditioner is opened. If the door is opened, step S114 is executed. On the other hand, in the case of the door closed state, the alignment waiting process is terminated and the system waits until the next system startup.

In this step S114, the riding capable water riding process is performed on the target machine. For example, if the number of people who have a capacity of 20 persons and the number of people who are already on board are 10 persons, and the boarding rate for the garden is 80%, then the number of people who can ride is (20 × 0.8) -10 = 6 persons. As a result, when the number of users waiting on the platform is six or less, the power can be ridden. When there are seven or more users waiting on the platform, the remaining users exceeding six are subjected to the hall waiting process Registration processing of the user.

In step S115, when the riding of the user waiting in the landing area is completed, the current system time is registered as the riding time.

As a result, the occurrence time, registration completion time, platform arrival time, and ride time are registered as the evaluation time on the platform of the user. By using these times, various simulations can be evaluated. As described above, the in-building user control unit 11 simulatively controls the conductor of the user.

Fig. 13 shows an example of the simulation result of the platform layout in which the installation position of the gate 105 is bad. In the simulation results shown below, also in Figs. 14 to 19 described later, in the same manner as the elevator equipment, each unit is arranged in the order of the first unit, the second unit, and the third unit from the upper left to the lower left And the fourth, fifth and sixth units are arranged in order from the upper right to the lower right.

An elevator 101 is installed in a predetermined arrangement and a hall lantern 102 and a landing destination floor registering device 103 are installed and a user 104 serving as a target circulating unit is waiting. The user 106 having the sixth unit as the target unit is staying in front of the lighting unit of the hall lantern 108. [ If certain conditions overlap, the user 107 passing through the gate 105 will not have a movable space due to the stay of the user 106 assigned to the sixth unit. Therefore, if the number of users of the user 107 increases, the number of users 107 who can not register in the gate increases, and the elevator has a serviceable CPU, but the time required for registration is worse than other simulation conditions and specifications Results.

Fig. 14 shows a simulation result of a platform layout in which the installation position of the gate 205 is good. The landing layout of the city has a space from the elevator 201 to the gate 205 when compared with the landing layout shown in Fig.

Therefore, even if the gate 205 is the closest to the gate 205 and a large number of users 204 are allocated to wait in a certain unit (" Unit 6 "), There is a space in which the user 206 can walk. Therefore, even when the number of users of the newly entering user 206 is increased, the number of users who can not register to be assigned to the gate 205 is not increased, so that the performance of the elevator can be sufficiently exhibited. As a result, the time required for registration does not increase excessively, resulting in a good evaluation result.

Fig. 15 shows a landing layout in which the number of installed gates 301 is extremely small in comparison with Fig. Since the number of the gates 301 is less than one half of the number of the gates 205 shown in Fig. 14, the retention due to the alignment of the user 302 in the gate 301 is likely to occur , The number of users who can pass through the gate 301 is limited. Therefore, although the number of users 302 that can not be registered to be allocated to the gate 301 increases, and the elevator is in a situation where a serviceable machine is likely to exist, the time required for registration is worse than other simulation conditions and specifications .

16 shows a layout in which simulations are carried out in a specification in which a hall up and down type button is provided and the hall lantern 402 is immediately lit. When the up / down platform button 401 is pressed, all the up / down platform buttons 401 of that layer are turned on. At this time, when the elevator is assigned to the second unit, the hall lantern 403 of the second unit is turned on. And the hall lantern 402 other than the second unit is turned off. The user 404 having the number of persons up to the specific threshold stays in front of the unit (the second unit) in which the hall lantern 403 is lit, while the user 405 having the number of waiting persons exceeding the specific threshold value is waiting for alignment Simulated.

Fig. 17 shows a layout in a case where simulations are carried out in a specification in which a lift up / down button is provided and a hall lantern is not immediately turned on. When the up / down type landing pad button 501 is pressed, all the up / down type landing pad buttons 501 of that layer are turned on. However, even if the second unit is allocated, the hall lantern 502 near the second unit does not light up. Since the assigned unit can not be recognized, the user 503 waits for alignment in the vicinity of the center of the landing area as shown in the figure.

Fig. 18 shows an example of a simulation result in a case in which a hall up and down type button is provided and a hall lantern is immediately lit up and the wheelchair elevator is the first wheel. When the up / down type landing pad button 601 is pressed, all the up / down type landing pad buttons 601 of that layer are turned on. When the second unit is assigned, the hall lantern 602 of the second unit is turned on. The wheelchair user 603 presses the wheelchair platform button near the first unit and aligns them as shown. As a result, the time required until registration of the wheelchair user 603 becomes longer, resulting in a bad evaluation result.

Fig. 19 shows an example of a simulation result in the case where the lift-up / down-type button is provided and the hall lantern 702 is immediately lit up and the wheelchair elevator is the third wheel.

When the upper-floor type landing pad button 701 is pressed, all the upper-floor type landing pad buttons 701 of that layer are lit. At this time, when the second unit is allocated, the hall lantern 702 of the second unit is turned on. For example, the wheelchair user 703 can push the wheelchair lift button 704 in the vicinity of the third unit, and a third unit is assigned. Therefore, since the hall lantern 702 of the third unit is turned on, the wheelchair user 703 can quickly register, and the time required for the registration becomes short, which is a good evaluation.

(3) Effects of the present embodiment

As described above, in the elevator simulator in the above embodiment, the in-building user control section 11 performs simulation while generating a user simulatively so that the user takes the behavior according to the elevator information and the building information.

According to such a configuration, it is possible to more accurately evaluate not only the influence of the installation of the building equipment, but also the influence on the user about the specification of the elevator equipment and the influence on the behavior of the user.

(4) Other Embodiments

The above embodiment is an example for explaining the present invention and is not intended to limit the present invention to these embodiments. The present invention can be embodied in various forms as long as it does not depart from its gist. For example, in the above-described embodiment, the processing of various programs has been explained in a sequential manner, but it is not particularly limited to this. Therefore, as long as there is no inconsistency in the processing results, the processing sequence may be replaced or operated in parallel.

The present invention can be widely applied to an elevator simulator that performs simulation according to an elevator installation.

1: User setting section
2: Building information setting section
3: Elevator facility setting section
4: Elevator specification setting section
5: Time zone setting unit
10: Simulation section
11: In-building user control unit
12: Input device
13: elevator group management control unit
14:
15: Landing platform output device
16: Elevator
17: Overall evaluation output section
100: Simulation system

Claims (4)

An elevator facility setting unit for setting elevator information about the elevator equipment;
A building information setting unit for setting building information on a building specification of the entire building;
A user setting section for setting user information including a generation time, a generation layer, a destination layer and an attribute of a user generated simulatively in the elevator installation;
An in-building user control unit for controlling the behavior of the user,
An elevator control unit for managing the operation by controlling the elevator equipment,
An input device for making a service request from the in-building user control section to the elevator control section;
A platform output device for outputting a result of the service request;
And,
The in-building user control unit,
And simulates the elevator information and the building information while simulating the user so as to take an action according to the elevator information and the building information. The method according to claim 1,
As a result of the simulation, the elevator information, the time required for registration for each user, the moving time, the time spent for extra movement, the waiting time for the platform, and the riding time until the user gets on and off the elevator And an integrated evaluation output unit for outputting at least one of the elevator simulator and the elevator simulator. The method according to claim 1,
The in-building user control unit,
The building information and the specific building information closest to the elevator information among other elevator information related to the elevator equipment of the other building, And the user information is set based on the specific building information and the specific elevator information. The method according to claim 1,
Wherein the building information setting unit and the elevator facility setting unit,
The building information and the specific elevator information that are the closest to the building information and the elevator information are selected from among the results of the simulation performed in the past and the building specification based on the specific building information and the building specification based on the specific elevator information And setting the elevator equipment.

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