JP7027362B2 - Elevator work management system - Google Patents

Description

The present invention relates to an elevator work management system.

Conventionally, when trying to track the behavior history of a worker who inspects and maintains an elevator in a building where an elevator is laid, the smart device (smartphone, smart watch, wearable device, etc.) possessed by the worker is used. There is known a technique for tracking and estimating the behavior of a worker using a GPS (Global Positioning System) mounted on a smartphone.

For example, in Patent Document 1, the behavior history of a worker is estimated by GPS, it is estimated that the worker has entered the site based on the current position of the worker and the position information of the planned work site, and the admission registration to the mobile terminal is performed. A work management system that encourages people to work is disclosed.

Japanese Unexamined Patent Publication No. 2014-51376

The work management system disclosed in Patent Document 1 uses GPS to track the behavior of the worker, but when trying to track by GPS, even if the position of the worker can be specified, the accuracy error of GPS. Therefore, it was difficult to track the detailed behavior of the worker. Therefore, it is estimated that the worker entered the building even during a break near the work site, and it is not possible to grasp the actual working time calculated from the difference between the times when the worker actually started and finished the work.

Actual working hours are important information for the manager to understand the actual situation of work and to pay the wages of workers, and if an error occurs, the manager's management of the worker will be hindered. .. In the prior art, sufficient solutions to these problems have not been considered, and it has not been easy to accurately estimate the behavior of the worker when GPS is used.

The present invention has been made in consideration of the above points, and is a work management system and a work management method capable of estimating the work start and end times of a worker who inspects and maintains an elevator with high accuracy. Is an attempt to propose.

In order to solve such a problem, in the present invention, the elevator work management system that estimates the action history of the worker who performs the work in the elevator is the elevator work management system, the terminal carried by the worker, and the terminal. Including servers that can communicate with
The terminal has a pressure sensor and a pressure sensor value registration unit that registers a pressure sensor value indicating a time-series change in the pressure value measured by the pressure sensor, and the server has the pressure sensor value registration unit. A storage unit that stores the pressure sensor value registered by the user, a work schedule in the elevator that is planned in advance, and a work scheduled in the work schedule in the elevator that is stored in the storage unit. The pressure sensor value included in the time is extracted from the storage unit, the behavior of the worker is estimated based on the extracted pressure sensor value, and it is estimated that the pressure sensor value is estimated to have been performed by the worker in the earliest time zone. Work start and end time determination unit that determines the execution time of each floor operation of the elevator as the work start time and determines the execution time of each floor operation of the elevator that is estimated to have been performed in the latest time zone as the work end time. It is characterized by having and.

According to the present invention, for example, the work start and end times of a worker who inspects and maintains an elevator can be estimated with high accuracy.

It is a schematic block diagram which shows the whole structure example of the elevator apparatus which is the object of inspection and maintenance work in one Embodiment of this invention. It is a block diagram which shows the structural example of the work management system which concerns on one Embodiment of this invention. It is a flowchart which shows an example of the work procedure of inspection and maintenance work in one Embodiment of this invention. It is a graph which shows an example of the time-series change of the relative atmospheric pressure value when the inspection and maintenance work in one Embodiment of this invention are carried out. It is a flowchart which shows the processing procedure example of the process of determining the work start and end time in one Embodiment of this invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. In the present specification, the same reference number of each drawing indicates the same or similar configuration or processing, and in the later description, only the difference from the above description is described, and the latter description may be omitted. be. In addition, each embodiment and each modification can be partially or wholly combined within the scope of the technical idea of the present invention and within the range consistent with each other.

<Structure of the target elevator device in the embodiment>
Prior to the description of the elevator work management system according to the embodiment of the present invention, the elevator device to be inspected and maintained in the embodiment of the present invention will be described. FIG. 1 is a schematic configuration diagram showing an overall configuration example of an elevator device to be inspected and maintained according to an embodiment of the present invention.

In the present embodiment, an example in which an elevator device 40 having one elevator car 3 is installed in a building having a floor on the F floor will be described. In the present embodiment, the illustration and description of the elevator car lift drive mechanism are omitted.

The elevator device 40 includes an elevator control device 2, an elevator car 3, and a landing operation panel 6. The car 3 moves between the landings on a plurality of floors by moving up and down. The car 3 is provided with a car control device 31. In the present embodiment, the elevator device 40 will be described as having one elevator car 3 but not limited to this, the elevator device 40 has a plurality of elevator car 3s. May be good.

The elevator control device 2 is provided in the machine room or hoistway of the elevator, and controls and manages the operation of the car 3. The elevator control device 2 is electrically connected to the car control device 31 of the car 3. The car control device 31 of the car 3 outputs the information of the destination floor registered in the car 3 to the elevator control device 2.

The elevator device 40 includes a power supply device (not shown) and an auxiliary power supply device that monitors the power supply state from the power supply device and has a backup power supply. The power supply and auxiliary power supply are installed in the machine room or hoistway of the elevator. When the power supply from the power supply is cut off due to a power failure, the auxiliary power supply automatically switches from the power supply from the power supply to the backup power supply, so that the power supply from the power supply is restored after the power failure occurs. Backup power is supplied to the elevator control device 2 and the car 3 respectively for the period up to.

In addition, the elevator platform 4 on each floor of the building has a pair of left and right doors 5 for the elevator, and usage reservation information including information on whether the destination floor when the user uses the elevator is upstairs or downstairs. There is also a landing operation panel 6 on which the registration can be performed. The configuration of the landing operation panel 6 provided in the elevator landing 4 on each floor is substantially the same. The landing operation panel 6 is electrically connected to the elevator control device 2. When the user operates the landing operation panel 6 to register the usage reservation information, the elevator control device 2 inputs the usage reservation information from the landing operation panel 6 to the elevator control device 2.

The elevator control device 2 contains usage reservation information from the landing operation panel 6, information on the destination floor of the user registered from the operation panel in the car (not shown), the position of the car 3, and the movement of the car 3. The direction and the operation information including the slide opening / closing operation of the pair of left / right opening / closing doors 5 of the car 3 are input respectively. Then, the elevator control device 2 manages the operation of the elevator based on the usage reservation information and the driving information, and reaches the car 3 on the floor where the landing operation panel 6 that outputs the usage reservation information is provided. Control the operation so that it is allowed to operate.

<Configuration of work management system according to the embodiment>
Hereinafter, a work management system according to an embodiment of the present invention will be described. FIG. 2 is a block diagram showing a configuration example of a work management system according to an embodiment of the present invention. As shown in FIG. 1, the work management system 1 according to the present embodiment includes a smart device 10 and a center device 20. The center device 20 is a server computer installed in a data center. The smart device 10 and the center device 20 are communicably connected via a network 30 which is a wide area network or a closed area network.

<Configuration of smart device according to the embodiment>
Next, the functional configuration of the smart device 10 will be described. The smart device 10 is an information terminal that is always carried (carried) by a worker engaged in inspection and maintenance work (hereinafter, also simply referred to as work) of the elevator device 40, and is, for example, a smartphone or a tablet terminal. Such as slate terminals, smart watches, or wearable devices.

As shown in FIG. 2, the smart device 10 includes a transmission / reception unit 11, a barometric pressure sensor 12, a barometric pressure sensor value registration unit 13, a display unit 14, and a storage unit 15.

The transmission / reception unit 11 is a communication interface, and transmits / receives data to / from the center device 20 via the network 30. Further, the atmospheric pressure sensor 12 is a sensor that detects atmospheric pressure.

The barometric pressure sensor value registration unit 13 registers the barometric pressure sensor value measured by the barometric pressure sensor 12. Specifically, the barometric pressure sensor value registration unit 13 continuously records the barometric pressure sensor value measured by the barometric pressure sensor 12 in the storage unit 15 (barometric pressure sensor value 151), and after the worker's work is completed, the storage unit 15 The barometric pressure sensor value 151 recorded in the above is transmitted to the center device 20 and stored in the storage unit 24 of the center device 20 (barometric pressure sensor value 243).

In the present embodiment, the barometric pressure sensor value 151 is collectively transmitted to the center device 20 after the worker's work is completed, but the present invention is not limited to this, and the barometric pressure sensor value 151 may be transmitted one by one. At this time, the time information of the clock (not shown) mounted on the smart device 10 is added to the barometric pressure sensor value 151 transmitted to the center device 20. It is preferable that the time of the clock is periodically corrected by communication with a communication device of a mobile phone company, for example, and by performing such correction, the error range is set to a predetermined amount (for example, less than 1 second). It can be suppressed.

The display unit 14 is, for example, a liquid crystal display, and has a keyboard function (input function) capable of inputting numbers and character information by touch operation like a smartphone, in addition to the display function. The operator can confirm the work schedule 241 stored in the storage unit 24 of the center device 20 by operating the display unit 14, and by confirming the work schedule 241 the work destination information and work contents. Can be recognized.

The storage unit 15 is a memory for recording data. Specifically, for example, the barometric pressure sensor value 151 registered by the barometric pressure sensor value registration unit 13 is stored.

Supplementing the hardware that realizes each functional configuration of the smart device 10 shown in FIG. 2, in the pressure sensor value registration unit 13, for example, the CPU (Central Processing Unit) mounted on the smart device 10 is ROM (Read). It can be realized by reading a predetermined program stored in (Only Memory) into RAM (Random Access Memory) and executing it. Further, the CPU may also control the display function and the input function in the display unit 14.

<Configuration of center device according to the embodiment>
Next, the functional configuration of the center device 20 will be described. The center device 20 is a management device that integrally manages a plurality of elevator devices 40, and is realized by, for example, a server or a database. The center device 20 is generally installed in a place remote from the place where the worker performs maintenance work, for example, in the building of the company to which the worker belongs. As shown in FIG. 2, the center device 20 includes a transmission / reception unit 21, a work schedule planning unit 22, a work start and end time determination unit 23, and a storage unit 24.

The transmission / reception unit 21 is a communication interface, and transmits / receives data to / from the smart device 10 via a network 30 which is a wide area network or a closed area network.

The work schedule planning unit 22 receives and registers a work schedule plan such as which work destination and when to visit while the worker patrols a plurality of work destinations. Specifically, for example, the worker adjusts the work date and time with the work requester (building owner or manager), and performs a predetermined input operation to the input unit (not shown) of the center device 20. , The work schedule planning unit 22 registers the work schedule with the input work destination (may include the unit information of the elevator device 40 of the work destination) and the work date and time. The work schedule to be registered is stored in the storage unit 24 (work schedule 241) and can be referred to by the smart device 10.

The work start and end time determination unit 23 performs inspection and maintenance work of the elevator device 40 based on the time-series relative barometric pressure value (barometric pressure sensor value 243) received from the smart device 10 and stored in the storage unit 24. It has a function to determine the start time and work end time, and a function to determine whether inspection and maintenance work have been performed.

The details will be described later with reference to FIG. 5, but the work start and end time determination unit 23 stores the work by executing the “work start and end time determination process” after the inspection and maintenance work of the elevator device 40 is completed. The behavior of the worker can be estimated from the barometric pressure sensor value 243 stored in the unit 24, and the work start time and the work end time can be determined. If the work start time and work end time cannot be determined, it can be determined that the inspection and maintenance work has not been performed.

The storage unit 24 is a memory for recording data. Specifically, as shown in FIG. 2, the storage unit 24 stores the work schedule 241 and the work start and end times 242, the barometric pressure sensor value 243, the operation state data 244, the work record 245, and the floor information 246. Will be done.

Of these, the work schedule 241 is data registered by the work schedule planning unit 22. The work schedule 241 includes identification information of the elevator device 40 to be worked, work contents, work time, and the like. The work schedule 241 may include unit information of the elevator device 40.

The work start and end time 242 is data registered by the work start and end time determination unit 23, which will be described later in FIG. The barometric pressure sensor value 243 and the work record 245 are data registered and transmitted from the smart device 10.

The operation state data 244 is operation record information that captures the operation status of various devices including the car 3 of the elevator device 40, the opening / closing door 5, and the like, and saves them in chronological order. The operation state data 244 is remotely collected in the center device 20 from a monitoring device or the like (not shown) of the elevator device 40, and is stored in the storage unit 24 one by one or collectively.

Further, the floor information 246 is data stored in the storage unit 24 in advance, and is data indicating the number of floors of the work destination building, etc., and is set in advance. In the present embodiment, the floor information 246 is used by being substituted into the calculation formula for calculating the relative atmospheric pressure reference value described later in FIG.

To supplement the hardware that realizes each functional configuration of the center device 20 shown in FIG. 2, the work schedule planning unit 22 and the work start and end time determination units 23 are, for example, CPUs mounted on the center device 20. Can be realized by reading a predetermined program stored in the ROM into the RAM and executing the program.

The network 30 is a wide area represented by the Internet, mobile high-speed wireless communication systems such as LTE (Long Term Evolution (registered trademark)) and 5G (5th generation mobile communication system), and WAN (Wide Area Network). It is a communication network or the like, and is a communication means for exchanging various data between the smart device 10 and the center device 20.

<Elevator inspection and maintenance work and changes in relative pressure value>
In the work management system 1 according to the present embodiment, the barometric pressure sensor 12 may be used while the smart device 10 carried by the worker is turned on (may be while a predetermined application is operating on the smart device 10). Is measuring the barometric pressure. Then, when the maintenance work of the elevator device 40 is carried out by the worker, the barometric pressure sensor value registration unit 13 shall perform the maintenance work from the time when the worker enters the target building until the worker leaves the building. The barometric pressure sensor value measured by the barometric pressure sensor 12 is continuously supplemented, and the barometric pressure sensor value at the reference point (for example, the first floor at the time of admission) is set as the reference value "0", and the relative barometric pressure value (hereinafter, relative barometric pressure value). The change of (referred to as) is recorded in the storage unit 15.

<Work procedure of inspection and maintenance work of the embodiment>
FIG. 3 is a flowchart showing an example of work procedures for inspection and maintenance work according to the embodiment of the present invention. FIG. 3 shows a work procedure of inspection work A whose work content is as an example of inspection and maintenance work of the elevator device 40 targeted in the present embodiment.

According to FIG. 3, the worker first confirms the work schedule (step S1). Specifically, for example, the worker operates the display unit 14 of the smart device 10 to refer to the work schedule 241 stored in the storage unit 24 of the center device 20 and confirms the work schedule of the day. Understand the work content, work start and end times, work address of the building, etc.

Next, as soon as the work start time arrives, the worker enters the building where the elevator device 40 is laid and starts the inspection and maintenance work (step S2). Next, the worker attaches an inspection tag (not shown) to the landing on each floor in order to inspect and maintain the elevator device 40 (step S3). The inspection tag is a sticker or the like posted to inform the user of the elevator device 40 that it cannot be used. It will be posted at the landing on each floor where the car 3 of the elevator device 40, which is generally easily noticed by the user, stops. This work must be performed before the start of work, regardless of the type of inspection and maintenance work, in consideration of the user.

Next, in step S4, the operator reciprocates the operation of the car 42 of the elevator device 40 on each floor, and confirms the floor step and the stop shock (impact at the time of stopping) at the time of landing on each floor (arrival). Check the floor level). At this time, the worker drives the car 3 while stopping it on each floor to perform a reciprocating operation. This inspection is performed in parallel with the work of attaching the inspection tag in step S3.

Next, the worker carries out the inspection and maintenance work A in step S5. In the inspection and maintenance work A in this embodiment, after the work in the machine room located on the roof of the building is carried out, the inspection work around the doors on each floor is carried out, and then the hoistway floor surface (pit) is cleaned and inspected. After performing the work, it shall return to the machine room.

Next, in step S6, the worker removes the inspection tag on each floor posted in step S3 in order to complete the inspection and maintenance work of the elevator device 40. This work must be done after the work is completed in consideration of the user. After that, the worker leaves the building in step S7.

The worker operates the display unit 14 of the smart device 10 during or after the inspection and maintenance work, and inputs the work record for the work schedule 241 of the storage unit 24 of the center device 20. When the input is made, the work record 245 is stored in the storage unit 24 of the center device 20 with the status of provisional completion. It is assumed that the work record 245 has a plurality of statuses that can be associated with each other, and in the present embodiment, the statuses of "not implemented", "provisional completed", and "implemented" are prepared.

As described above, in the work management system 1 according to the present embodiment, the sensor atmospheric pressure value is measured by the smart device 10 carried by the worker during the above maintenance work, and the reference point (for example, 1 at the time of admission) is measured. The time-series change of the relative barometric pressure value with the barometric pressure sensor value in the floor) as the reference value “0” is recorded in the storage unit 15. Then, the time-series data of the relative barometric pressure value recorded in the storage unit 15 is transmitted to the center device 20, and is stored in the storage unit 24 as the barometric pressure sensor value 243.

Here, since the barometric pressure value is fluctuation information that fluctuates in the vertical direction with respect to the ground surface, the time-series change of the relative barometric pressure value in a series of inspection and maintenance work correlates with the vertical movement of the worker in the maintenance work. .. Therefore, in the center device 20, the work start and end time determination unit 23 uses the floor information 246 of the work destination stored in the storage unit 24 to refer to the relative atmospheric pressure value of each floor (relative atmospheric pressure reference value). ) Can be calculated, and by comparing the calculated relative barometric pressure reference value with the time-series relative barometric pressure value (barometric pressure sensor value 243) stored in the storage unit 24, which worker is in the inspection and maintenance work? It is possible to accurately track and grasp the behavior history of the worker, such as which floor he / she was on at the time.

<Time-series changes in relative atmospheric pressure values during inspection and maintenance work in the embodiment>
FIG. 4 is a graph showing an example of time-series changes in the relative atmospheric pressure value when the inspection and maintenance work according to the embodiment of the present invention is carried out. On the left side of FIG. 4, an F-story building in which the elevator device 40 can be stopped is shown on each floor, and the machine room 50 is at the top corresponding to the "F + 1" floor of the building, and the building "-1". The hoistway floor (pit) is represented at the bottom corresponding to the floor.

Further, in the graph of the time-series change of the relative atmospheric pressure value shown in FIG. 4, the vertical axis represents the relative atmospheric pressure value and the horizontal axis represents the passage of time. As for the relative pressure value, the atmospheric pressure on the reference floor (first floor in this example) is set as the reference pressure value “0”. In this example, it is assumed that the heights between the floors of the building are the same, and the pressure change value for the first floor is P. In this way, the relative atmospheric pressure reference value of each floor is "0" on the first floor, "-P" on the second floor, "-2P" on the third floor, ..., "-(F-1) on the F floor. ) × P ”, similarly, the relative pressure reference value of the machine room (F + 1st floor) is“ -F × P ”, and the relative pressure reference value of the hoistway floor (-1st floor) is“ P ”. ]. Further, the passage of time on the horizontal axis includes each step of the series of maintenance work shown in FIG. 3 (steps S3 to S6 in FIG. 3), and the relative atmospheric pressure value corresponding to each step. (A line graph in which the relative atmospheric pressure values based on the measured values by the atmospheric pressure sensor 12 are plotted in time series) are designated by the reference numerals of the atmospheric pressure changes H1 to H4.

Hereinafter, each pressure change H1 to H4 in FIG. 4 will be described in detail in comparison with the progress of each step of the maintenance work shown in FIG.

First, when admission registration is performed (step S3 in FIG. 3), the barometric pressure sensor value registration unit 13 sets the barometric pressure sensor value measured by the barometric pressure sensor 12 as the reference value “0”, and thereafter, the barometric pressure sensor value registration. The unit 13 converts the barometric pressure sensor value measured by the barometric pressure sensor 12 into a relative value (relative barometric pressure value) with respect to the reference value and handles it. In general, the barometric pressure sensor 12 may have a considerable measurement error, but the barometric pressure sensor value registration unit 13 sets a reference value at the time of admission registration and then handles it as a relative expected value, so that the measurement up to that point is performed. The error can be reset and the measurement error can be suppressed during a series of inspection and maintenance work.

When the inspection and maintenance work is started, the work of attaching the inspection tag is performed in each floor operation (step S3 in FIG. 3). At this time, the operator stops the car 3 on each floor while driving the car 3 and attaches the inspection tag. Therefore, the atmospheric pressure change H1 is a graph of the shape of moving each floor in a staircase pattern as shown in FIG. expressed.

Next, the landing level of the car 3 is confirmed (step S4 in FIG. 3). At this time, the operator confirms the floor step and the stop shock (impact at the time of stopping) at the time of landing on each floor while driving the car 3. Since this work is also carried out by stopping at each floor, the atmospheric pressure change H2 is represented by a graph having a shape of moving each floor in a staircase pattern as shown in FIG.

Next, inspection and maintenance work A is carried out (step S5 in FIG. 3). At this time, the worker performed the work in the machine room 50 located on the roof of the building, then inspected around the doors on each floor, and then inspected the hoistway floor (pit). After that, it returns to the machine room 50. The pressure change H3 moves from the 1st floor to the machine room (equivalent to the F + 1 floor), then to the hoistway floor (equivalent to the -1st floor), and then moves from the 1st floor to the machine room (equivalent to the F + 1 floor) again. It is represented by a graph of the shape to be used.

Since the worker uses the stairs to move between the top floor (F floor) and the machine room (F + 1 floor), the pressure change H3 is temporarily moved to the top floor (F floor) to move to the stair room. It becomes a graph with a shape that stays in the air. Similarly, when moving between the 1st floor and the floor of the hoistway (corresponding to the 1st floor), a simple ladder or the like is used, so that the atmospheric pressure change H3 temporarily stays on the 1st floor in preparation for the ladder. The graph has a different shape.

Next, when the inspection and maintenance work is completed, the work of removing the inspection tag is performed in each floor operation (step S6 in FIG. 3). At this time, since the operator stops the car 3 on each floor and removes the inspection tag while driving the car 3, the atmospheric pressure change H4 is represented by a graph having a shape of moving each floor in a staircase pattern. When all the inspection and maintenance processes are completed, the worker leaves the building from the first floor, so that the final relative atmospheric pressure value is "0".

As described in detail with reference to FIGS. 2 and 3, the work start and end time determination unit 23 determines the relative pressure reference value of each floor of the building and the time-series relative pressure value (barometric pressure sensor) measured in the maintenance work. By comparing with the value 243), it is possible to identify the vertical movement history (behavior history) of the worker, which is the time and floor on which the worker was in the maintenance work. Further, the work start and end time determination unit 23 determines the work start and end times of the worker by executing the following work start and end time determination processes, and determines whether or not the inspection and maintenance work has been carried out. judge. In the example shown in FIG. 4, "10:00" is estimated as the work start time, "11:00" is estimated as the work end time, and inspection and maintenance are performed between "10:00" and "11:00". It is a patrol schedule of work.

<Process for determining work start and end times in the embodiment>
FIG. 5 is a flowchart showing an example of a processing procedure for determining work start and end times in one embodiment of the present invention. In the work start and end time determination process shown in FIG. 5, at any time when the barometric pressure sensor value 243 and the work record 245 related to the inspection and maintenance work are aligned in the storage unit 24, for example, the operator performs the target inspection and maintenance work. After the work result registration is completed, the work is mainly executed by the work start and end time determination unit 23.

First, in step S11, the work start and end time determination unit 23 extracts the barometric pressure sensor value 243 within the time planned in the work schedule 241 from the storage unit 24 (step S11). Here, if it is assumed that the inspection and maintenance work will be started earlier than the planned time, or that the work will not be completed and will continue even after the planned time, the time to extract the barometric pressure sensor value 243 is set. It may be enlarged. Further, the barometric pressure sensor value 243 may be extracted by estimating the position information of the worker by GPS and extracting it in the time zone in the vicinity of the building.

Next, in step S12, the work start and end time determination unit 23 refers to the barometric pressure sensor value 243 extracted in step S11, and determines whether or not the user has moved to each floor "twice" or more. More specifically, in the pressure sensor value 243 extracted in step S11, the work start and end time determination unit 23 moves the car 3 while staying on each floor (0, -P, -2P, ... ·,-(F-1) × P) is recorded within each specified time (for example, residence time 30 seconds × stop floor (within 150 seconds in the case of the 5th floor)), and so on. It is determined whether or not various patterns have been recorded twice or more. At this time, the ascending and descending driving directions and the order of the stop floors shall be determined as appropriate. Further, the above-mentioned specified time is arbitrarily determined in consideration of the time spent for the work of attaching the inspection tag on the single floor from the speed of the elevator device 40, the floor height, the door speed, and the like. In the example shown in FIG. 4, since the four atmospheric pressure changes H1 to H4 are extracted in step S12, it is determined that the movement to each floor has been performed "twice" or more.

If it is determined in step S12 that the movement to each floor has been performed two or more times (YES in step S12), the work start and end time determination unit 23 proceeds to step S13. On the other hand, if it is determined in step S12 that the movement to each floor has not been performed two or more times (NO in step S12), the work start and end time determination unit 23 has not performed the inspection and maintenance work correctly. Since it can be estimated, the process proceeds to step S18. Step S18 is a process performed when it is determined that the inspection and maintenance work has not been performed correctly, and the details will be described later.

In step S12, the number of determinations of "twice" in which the work start and end time determination unit 23 determines whether or not the worker has moved to each floor is only an example. As the number of times of determination, other values may be adopted as long as it can be determined that the inspection work of the elevator has been carried out according to the work type of the inspection and maintenance work.

In step S13, the work start and end time determination unit 23 refers to the barometric pressure sensor value 243 extracted in step S11, provisionally determines each floor movement performed at the earliest time as the work start time, and works of the storage unit 24. Store at start and end times 242.

Next, in step S14, the work start and end time determination unit 23 refers to the barometric pressure sensor value 243 extracted in step S11, and the work start and end time determination unit 23 refers to each floor movement performed at the latest time. It is tentatively determined as the work end time and stored at the work start and end times 242.

Next, in step S15, the work start and end time determination unit 23 extracts the operation state data 244 within the inspection time of the elevator device 40 planned by the work schedule, which is stored in the storage unit 24. At this time, when the elevator device 40 includes a plurality of units, a work schedule is specified for each unit, and the operation state data 244 is extracted by designating the unit for which the inspection within the time is planned.

Next, in step S16, the work start and end time determination unit 23 has a waveform showing the transition of the barometric pressure sensor value 243 between the work start time and the work end time tentatively determined above, and the operation state data stored in the storage unit 24. 244 is compared, and it is determined whether or not the waveform of the barometric pressure sensor value 243 and the operating state data 244 match. Specifically, for example, when the work start and end time determination unit 23 changes the barometric pressure sensor value 243 as 0, −P, -2P, ..., − (F-1) × P, At the same time, the operation status data 244 was operated on the 1st floor, the 2nd floor, the 3rd floor, ... Judge whether or not.

In the determination of step S16, when it is determined that the car 3 has been operated as in the barometric pressure sensor value 243 (YES in step S16), the work start and end time determination unit 23 shifts the process to step S17. In step S17, the work start and end time determination unit 23 finally determines the work start time tentatively determined in step S13 and the work end time tentatively determined in step S14, and sets the status of the work start and end time 242 to "". Change to "final decision".

In the determination of step S16, the waveform of the barometric pressure sensor value 243 at the work start time and the work end time tentatively determined based on the work schedule of the elevator device 40 designated as the unit was extracted by designating the unit in step S15. The operating state data 244 of the elevator device 40 may be compared. At this time, if the waveform of the barometric pressure sensor value 243 and the operating state data 244 of the elevator device 40 extracted by designating the unit match, it is determined that the inspection and maintenance work have been performed correctly at the planned unit. On the other hand, in the determination of step S16, when the waveform of the barometric pressure sensor value 243 and the operation state data 244 extracted by designating the unit of the elevator device 40 do not match, the inspection and maintenance work are correctly performed at the scheduled unit. It is judged that it has not been broken. As a result, when the elevator device 40 includes a plurality of units, it is possible to detect a work omission in the car 3 of the unit to be inspected and maintained.

Step S17 is executed when affirmative results are obtained in steps S12 and S16 described above, and it is determined that the inspection tag affixing and removal operations for inspection and maintenance work have been performed correctly. At this time, the work start and end time determination unit 23 (or the work schedule planning unit 22) re-registers the status of the work record 245 registered in the work record 245 from "provisional completion" to "implemented". In addition, the work start and end time determination unit 23 (or work schedule planning unit 22) informs the administrator that the series of maintenance work has been normally performed by using a screen for registering the schedule plan, e-mail, or the like. You may want to report.

On the other hand, when it is determined in the determination of step S16 that the car is not operating as in the barometric pressure sensor value 243 (NO in step S16), the work start and end time determination unit 23 shifts the process to step S18. ..

On the other hand, in step S18, the work start and end time determination unit 23 (or the work schedule planning unit 22) re-registers the status of the work record 245 registered in the work record 245 from "provisional completion" to "not implemented". ..

Step S18 is executed when a negative result is obtained in either step S12 or step S16 described above, and it is determined that either the start or end of the inspection and maintenance work, or both, have not been performed correctly. Will be done. At this time, the work schedule planning unit 22 alerts the worker using a screen for registering the schedule plan, an e-mail, or the like, and warns that the work needs to be replanned. Further, the work start and end time determination unit 23 (or the work schedule planning unit 22) re-registers the status of the work record 245 registered in the work record 245 from "provisional completion" to "not implemented".

In the warning in step S18, it may be possible to output in which step of the series of maintenance work the abnormality is determined based on the determination result of at least one of step S12 and step S16. For example, according to the negative result of step S12, it is presumed that the worker has not performed either the inspection tag sticking or removing work that is always performed at the start and end of the work in the inspection and maintenance work. Further, in the negative result of step S16, it is said that there was a problem in the work of the operator in the step of determining that there is a discrepancy between the time-series transition of the barometric pressure sensor value 243 and the time-series transition of the operating state data 244 of the car 3. Presumed. By doing so, the manager can grasp in detail where the problem occurred in the worker's behavior history, and can utilize it for evidence of work implementation, educational activities, and the like.

When step S17 or step S18 is completed, the work start and end time determination unit 23 ends the work start and end time determination process. The status "provisional completion" of the work record 245 registered by the display unit 14 through the process of step S17 or step S18 is "completed" indicating that the work has been normally performed, or the work has been normally performed. It is not updated to "Not implemented" indicating that replanning or re-implementation is necessary, and the final status of work record 245 is confirmed.

As described above, according to the work management system 1 according to the present embodiment, as described in detail with reference to FIGS. 3 and 4, based on the time-series changes in the relative barometric pressure values (barometric pressure sensor values 151 and 243). It is possible to trace and grasp the action history of the worker in the inspection and maintenance work of the elevator device 40 (more specifically, the work start time and the work end time) with high accuracy. Further, by executing the work start and end time determination processes shown in FIG. 5, the inspection tag sticking and removing work that the worker always carries out at the start and end of the work in the inspection and maintenance work is described. Based on the time-series change of the relative atmospheric pressure value, it is possible to judge with high accuracy whether or not it was carried out normally. Thus, according to the work management system 1 according to the present embodiment, the actual working time of the inspection and maintenance work can be accurately grasped. In addition, since the manager can grasp the problem from the highly accurate action history of the worker, it can be utilized for evidence of work implementation, educational activities, and the like.

In this embodiment, the case of one worker has been described, but even if there are a plurality of workers, the same determination can be made by targeting the barometric pressure sensor values for all the workers. Can be done. Further, in the present embodiment, the inspection and maintenance work in the elevator device 40 has been described as an example, but the present invention can be applied to various works in the elevator including movement to each floor.

Further, each of the above configurations, functions, processing units, processing means and the like may be realized by hardware by designing a part or all of them by, for example, an integrated circuit. Further, each of the above configurations, functions, and the like may be realized by software by the processor interpreting and executing a program that realizes each function. Information such as programs, tables, and files that realize each function can be placed in a memory, a recording device such as a hard disk or SSD (Solid State Drive), or a recording medium such as an IC card, SD card, or DVD.

Further, in the drawings, the control lines and information lines are shown as necessary for explanation, and not all the control lines and information lines are necessarily shown in the product. In practice it may be considered that almost all configurations are interconnected.

The present invention is not limited to the above-described embodiment, and includes various modifications. For example, the above-described embodiments have been described in detail in order to explain the present invention in an easy-to-understand manner, and are not necessarily limited to those having all the described configurations. Further, it is possible to replace a part of the configuration of one embodiment with another configuration, and it is also possible to add another configuration to the configuration of one embodiment. Further, it is possible to add, delete, replace, integrate, or disperse other configurations with respect to a part of the configurations of the embodiment. Further, each configuration and each process shown in the embodiment may be appropriately distributed or integrated based on the processing efficiency or the mounting efficiency.

1: Work management system, 10: Smart device, 12: Barometric pressure sensor, 13: Barometric pressure sensor value registration unit, 14: Display unit, 15: Storage unit, 20: Center device, 22: Work schedule planning unit, 23: Work start And end time determination unit, 24: storage unit, 30: network, 31: control device, 40: elevator device

Claims (4)

An elevator work management system that estimates the behavior history of workers who perform work in elevators.
The elevator work management system includes a terminal carried by the worker and a server capable of communicating with the terminal.
The terminal is
Atmospheric pressure sensor and
It has a barometric pressure sensor value registration unit for registering a barometric pressure sensor value indicating a time-series change of the barometric pressure value measured by the barometric pressure sensor.
The server
A storage unit for storing the barometric pressure sensor value registered by the barometric pressure sensor value registration unit, a work schedule in the elevator planned in advance, and a storage unit.
The pressure sensor value included in the work time planned in the work schedule at the elevator stored in the storage unit is extracted from the storage unit, and the worker's pressure sensor value is used based on the extracted pressure sensor value. The behavior is estimated, and the worker determines that the operation time of each floor of the elevator, which is estimated to have been performed in the earliest time zone, is the work start time, and the elevator is estimated to have been performed in the latest time zone. An elevator work management system characterized by having a work start and end time determination unit that determines the execution time of each floor operation as the work end time. The work start and end time determination unit
It is determined whether or not the transition of the barometric pressure sensor value between the work start time and the work end time indicates that the operation of each floor of the elevator has been performed a predetermined number of times or more, and the operation of each floor of the elevator is the predetermined number of times. The elevator work management system according to claim 1, wherein when it is determined that the work has not been performed more than the number of times, it is determined that the work based on the work schedule has not been performed. The work start and end time determination unit
The transition of the barometric pressure sensor value between the work start time and the work end time is compared with the operation record information of the elevator.
When the transition of the barometric pressure sensor value and the movement of each floor of the elevator indicated by the operation record information match, it is determined that the work based on the work schedule has been completed.
The elevator according to claim 1 or 2, wherein when the transition of the barometric pressure sensor value and the movement of each floor of the elevator indicated by the operation record information do not match, it is determined that the work based on the work schedule has not been performed. Work management system. The work schedule includes information on the unit of the elevator to be worked on.
The work start and end time determination unit
The transition of the barometric pressure sensor value between the work start time and the work end time is compared with the operation record information specifying the elevator unit.
When the transition of the barometric pressure sensor value and the movement of each floor of the elevator indicated by the operation record information match, it is determined that the work based on the work schedule has been completed.
The elevator work management according to claim 3, wherein when the transition of the barometric pressure sensor value and the movement of each floor of the elevator indicated by the operation record information do not match, it is determined that the work based on the work schedule has not been performed. system.

Images