JPWO2019193656A1 - Elevator data acquisition system - Google Patents

Abstract

An object of the present invention is to provide a data acquisition system (1) capable of distributing communication for obtaining operation data of the same reporting period at different times for each of a plurality of storage devices. The data acquisition system (1) comprises a plurality of remote monitoring devices (13) and a data acquisition device (14). Each of the plurality of remote monitoring devices (13) stores the operation data of the corresponding elevator (2) while updating it. Each of the plurality of remote monitoring devices (13) stores reproduction data. The reproduction data is data for reproducing the operation data at the switching time of the reporting period after the switching time. The data acquisition device (14) acquires reproduction data from each of the plurality of remote monitoring devices (13) at different times after the switching time.

Description

  The present invention relates to an elevator data acquisition system.

  Patent Document 1 describes an example of a data acquisition system. The data acquisition system includes a plurality of storage devices and a data acquisition device. Each of the plurality of storage devices reads out data representing the driving state from the elevator and stores it as driving data. The data acquisition device distributes communication for obtaining operation data stored in each of the plurality of storage devices at different times.

Japanese Patent Laid-Open No. 10-302180

  However, in the data acquisition system described in Patent Document 1, the operation data acquired by the data acquisition device is the operation data at the acquired time. That is, the data acquisition device acquires operation data at different times from each of the plurality of elevators. On the other hand, when the reporting period for which the operating data is to be obtained is specified, the operating data at the switching time of the reporting period is required. Therefore, the data acquisition device cannot disperse the communication for obtaining the operation data of the same reporting period at different times for each of the plurality of storage devices.

  The present invention has been made to solve such problems. An object of the present invention is to provide a data acquisition system capable of distributing communication for obtaining operation data of the same reporting period at different times for each of a plurality of storage devices.

  In the elevator data acquisition system according to the present invention, the elevator operation data is stored while being updated, and the reproduction data for reproducing the operation data at the switching time of the reporting period after the switching time is stored in each of a plurality of storage units. And a data acquisition device that acquires reproduction data at different times after the switching time from each of the plurality of storage devices.

  According to the present invention, each of the plurality of storage devices stores the reproduction data. The reproduction data is data for reproducing the operation data at the switching time of the reporting period after the switching time. The data acquisition device acquires reproduction data from each of the plurality of storage devices at different times after the switching time. Thereby, the data acquisition system can distribute the communication for obtaining the operation data of the same reporting period at different times for each of the plurality of elevators.

It is a block diagram of a data acquisition system according to the first embodiment. FIG. 6 is a diagram showing an example of a data acquisition table according to the first embodiment. FIG. 3 is a diagram showing an example of data in the data acquisition system according to the first embodiment. 5 is a flowchart showing an example of operation of the remote monitoring device according to the first embodiment. 5 is a flowchart showing an example of operation of the data acquisition device according to the first embodiment. 2 is a diagram showing a hardware configuration of a main part of the data acquisition system according to the first embodiment. FIG. FIG. 8 is a diagram showing an example of data in the data acquisition system according to the second embodiment. It is a figure which shows the example of the data in the data acquisition system which concerns on Embodiment 3. 9 is a flowchart showing an example of operation of the remote monitoring device according to the third embodiment. It is a figure which shows the example of the data in the data acquisition system which concerns on Embodiment 4. It is a figure which shows the example of the data in the data acquisition system which concerns on Embodiment 5.

  Embodiments for carrying out the present invention will be described with reference to the accompanying drawings. In each drawing, the same or corresponding parts are denoted by the same reference numerals, and the overlapping description is appropriately simplified or omitted.

Embodiment 1.
FIG. 1 is a configuration diagram of a data acquisition system according to the first embodiment.

  The data acquisition system 1 is applied to each of the elevators 2.

  Each of the plurality of elevators 2 is provided in each of the plurality of buildings 3.

  Each of the plurality of buildings 3 has a plurality of floors. In each of the plurality of buildings 3, the hoistway 4 penetrates each of the plurality of floors. Each of the plurality of buildings 3 has a plurality of halls 5. Each of the plurality of halls 5 is provided on each of the plurality of floors. Each of the plurality of landings 5 faces the hoistway 4. Each of the plurality of halls 5 includes a hall door 6.

  Each of the plurality of elevators 2 includes a car 7, a balance weight 8, a hoisting machine 9, a main rope 10, and a control panel 11.

  The car 7 is provided so as to be able to move up and down inside the hoistway 4. The car 7 includes a car door 12. The car door 12 is configured such that when the car 7 is stopped at any of a plurality of floors, the hall door 6 can be interlocked to open and close.

  The balance weight 8 is provided so as to be able to move up and down inside the hoistway 4.

  The hoisting machine 9 is provided in the upper part inside the hoistway 4.

  The main rope 10 is wound around the hoisting machine 9. Both ends of the main rope 10 are held by the car 7 and the balance weight 8, respectively.

  The control board 11 is provided in the upper part inside the hoistway 4. The control panel 11 is connected to the car 7 so as to control the operation of the car 7. The operation of the car 7 includes opening and closing the car door 12. The control board 11 is connected to the hoisting machine 9 so as to control the operation of the hoisting machine 9. The operation of the hoisting machine 9 includes starting and stopping. The control panel 11 is configured to be able to receive status data from the car 7 and the hoist 9. The state data is data representing the operating state of the elevator 2.

  The data acquisition system 1 includes a plurality of remote monitoring devices 13 and a data acquisition device 14.

  Each of the plurality of remote monitoring devices 13 is an example of a storage device. Each of the plurality of remote monitoring devices 13 corresponds to each of the plurality of elevators 2. Each of the plurality of remote monitoring devices 13 is provided in, for example, a management room of the building 3 in which the corresponding elevator 2 is installed. Each of the plurality of remote monitoring devices 13 includes a first storage unit 131, a generation unit 132, a second storage unit 133, and a transmission unit 134.

  The first storage unit 131 is connected to the control panel 11 so as to receive the status data. The first storage unit 131 is configured to store the operation data while updating the operation data according to the received state data. The operation data is data representing the operation state of the elevator 2. Here, the driving state includes, for example, driving history and information on abnormality or modulation. Modulation is the change before it becomes abnormal.

  The generation unit 132 is connected to the first storage unit 131 so that the operation data can be acquired. The generation unit 132 is configured to be able to generate reproduction data from the operation data at the switching time of the reporting period. The reporting period is a period during which the operation history of the elevator 2 and any abnormality or modulation are reported to the administrator of the elevator 2 or the like. The switching time is the start time or end time of the reporting period. The reporting period is stored in the generation unit 132. The reproduction data is data for reproducing the operation data at the switching time of the reporting period. The generation unit 132 is connected to the second storage unit 133 so that the reproduction data can be updated.

  The second storage unit 133 is configured to store the reproduction data.

  The transmission unit 134 is connected to the second storage unit 133 so that the reproduction data can be acquired. The transmission unit 134 is connected to the data acquisition device 14 through the communication line 15 so that the reproduction data can be transmitted. The communication line 15 is, for example, a telephone line.

  The data acquisition device 14 includes a data acquisition unit 141, an operation data storage unit 142, and a report data generation unit 143.

  The data acquisition unit 141 is connected to each of the plurality of remote monitoring devices 13 through the communication line 15 so that the reproduction data can be received based on the data acquisition table. The data acquisition table is a table in which the reporting period and the data acquisition time are associated with each other for each of the elevators 2. The data acquisition time is the time at which each of the remote monitoring devices 13 corresponding to each of the plurality of elevators 2 and the data acquisition unit 141 perform data communication. As the data acquisition time, different times are set for each of the plurality of elevators 2. The data acquisition unit 141 is configured to be able to reproduce the operation data at the switching time of the reporting period based on the acquired data. The data acquisition unit 141 is connected to the operation data storage unit 142 so that the reproduced operation data can be transmitted.

  The operation data storage unit 142 is configured to be able to store operation data.

  The report data generation unit 143 is connected to the operation data storage unit 142 so that the operation data can be acquired. The report data generation unit 143 is configured to generate report data based on the acquired operation data. The report data includes a history of the operation of the elevator 2 during the report period and an abnormality or modulation.

  In the operation of the elevator 2, the control panel 11 activates the hoisting machine 9. The main rope 10 is driven by the hoist 9 and moves. The car 7 and the balance weight 8 move up and down along a guide rail (not shown) following the movement of the main rope 10. The car 7 stops on the floor where the hall 5 is provided. The landing door 6 opens in conjunction with the car door 12. The user of the elevator 2 gets on or off the car 7 from the hall 5.

  The control panel 11 stores the operation data while updating it. At the switching time of the reporting period, the control panel 11 generates the reproduction data. The data acquisition device 14 acquires the reproduction data from each of the plurality of elevators 2 at different times based on the data acquisition table. The data acquisition device 14 reproduces the operation data from the reproduction data. The data acquisition device 14 generates report data from the reproduced operation data.

Next, an example of the data acquisition table will be described with reference to FIG.
FIG. 2 is a diagram showing an example of the data acquisition table according to the first embodiment.

  The data acquisition table is stored in the data acquisition unit 141.

  The data acquisition table associates, for example, a reporting period, a report data generation time, and a data acquisition time for each of the plurality of elevators 2. The report data generation time is the time when the data acquisition device 14 generates the report data from the reproduced operation data. The end time of the reporting period is the start time of the next reporting period. Here, 24:00 on a certain day is the same time as 0:00 on the next day. The reporting period in which the data acquisition table is associated with each of the plurality of elevators 2 is the same as the generation unit 132 of the remote monitoring device 13 corresponding to each of the elevators 2.

  In this example, the reporting period of the elevator E1 is from 0:00 on the first day of every month to 24:00 on the last day. The end time of the reporting period of the elevator E1 is 24:00 on the last day of every month. The report data generation time of the elevator E1 is 12:00 on the 15th day of the following month. The data acquisition time of the elevator E1 is 0:30 on the 5th day of the following month.

  The reporting period of the elevator E2 is from 0:00 on the first day of every month to 24:00 on the last day. The report data generation time of the elevator E2 is 12:00 on the 20th day of the following month. The data acquisition time of the elevator E2 is 3:00 on the 10th day of the following month.

  The reporting period of the elevator E3 is from 0:00 on the first day of every month to 24:00 on the last day. The report data generation time of the elevator E3 is 12:00 on the 20th day of the following month. The data acquisition time of the elevator E3 is 4:45 on the 15th day of the following month.

  The reporting periods of the elevators E1, E2 and E3 are the same. The data acquisition times of the elevator E1, the elevator E2, and the elevator E3 are different from each other.

Next, the function of the data acquisition system 1 will be described with reference to FIG.
FIG. 3 is a diagram showing an example of data in the data acquisition system according to the first embodiment.
In FIG. 3, the case where the report data for March is generated for the elevator E2 in FIG. 2 will be described as an example.

  The operation data D1 includes history data Da and measurement data Db. The history data Da is data to which an element associated with time is added by updating. The element of the history data Da is, for example, a code indicating the time associated with the time when the abnormality or the modulation event occurs. In FIG. 3, only the date is displayed among the times associated with the elements. The measurement data Db is data whose element values change due to updating. The elements of the measurement data Db are, for example, the number of times the hoisting machine 9 is started, the cumulative traveling time of the car 7, or the number of times the car door 12 is opened and closed. In FIG. 3, the number of times of activation is displayed as an example of a part of the elements of the measurement data Db.

  When receiving the state data representing an abnormal or modulation event, the first storage unit 131 adds a code representing the event in association with the time when the event occurred as an element of the history data Da. The first storage unit 131 continues to store the added element within the storage capacity range. When the storage capacity is insufficient, the first storage unit 131 deletes the element having the oldest associated time. The first storage unit 131 has a sufficient storage capacity so that elements are not deleted for at least two months or more, for example. That is, the first storage unit 131 stores history data Da including information before March.

  When receiving the state data indicating the activation of the hoisting machine 9, the first storage unit 131 adds 1 to the element value of the measurement data Db indicating the number of times the hoisting machine 9 has been activated. The first storage unit 131 stores, for example, the number of activations accumulated for at least two months or more as one value of the elements of the measurement data Db. That is, the first storage unit 131 stores the measurement data Db including the information before March.

  The generation unit 132 of the remote monitoring device 13 acquires the operation data D1 from the first storage unit 131 at 0:00 on March 1. 0:00 on March 1st is the end time of the reporting period in February and the starting time of the reporting period in March. The generation unit 132 generates the reproduction data D2 by copying the acquired operation data D1. The reproduction data D2 generated by the generation unit 132 is the same as the operation data D1 at 0:00 on March 1. That is, the reproduction data D2 includes history data Da and measurement data Db. The generation unit 132 transmits the reproduction data D2 to the second storage unit 133.

  The second storage unit 133 stores the reproduction data D2. The second storage unit 133 updates the stored reproduction data D2 by overwriting with the reproduction data D2 received from the generation unit 132. During the reporting period of March, the second storage unit 133 stores the reproduction data D2 that is the same as the operation data D1 at 0:00 on March 1.

  The data acquisition unit 141 of the data acquisition device 14 transmits a data request signal to the remote monitoring device 13 corresponding to the elevator E2 at 3:00 on March 10. 3:00 on March 10th is the data acquisition time associated with the elevator E2 by the data acquisition table.

  When the data request signal is received, the transmission unit 134 of the remote monitoring device 13 acquires the reproduction data D2 from the second storage unit 133. The transmission unit 134 transmits the reproduction data D2 to the data acquisition unit 141.

  The data acquisition unit 141 reproduces the operation data D1 at 0:00 on March 1 by copying the acquired reproduction data D2. The data acquisition unit 141 transmits the reproduced operation data D1 to the operation data storage unit 142.

  The operation data storage unit 142 stores the received operation data D1 at the end time of the reporting period of February.

  Similarly in April, the data acquisition device 14 reproduces the operation data D1 at 0:00 on April 1 by the reproduction data D2 acquired at 3:00 on April 10. 0:00 on April 1st is the end time of the reporting period in March and the starting time of the reporting period in April. 3:00 on April 10th is the data acquisition time associated with the elevator E2 by the data acquisition table.

  At the report data generation time of the elevator E2, the report data generation unit 143 acquires the operation data D1 at the end time of the reporting period of February and the operation data D1 at the end time of the reporting period of March from the operation data storage unit 142. . The report data generator 143 generates report data D3 based on the acquired operation data D1.

  The report data generation unit 143 extracts elements that are not included in the history data Da at the end time of the reporting period in February and are included in the history data Da at the end time of the reporting period in March. In this example, the report data generation unit 143 extracts an element representing the event B occurring on March 2 and an element representing the event C occurring on March 12. The report data generation unit 143 sets the extracted element as the history data Da of the report data D3.

  The report data generation unit 143 calculates the difference between the value of the element of the measurement data Db at the end time of the reporting period in February and the value of the element of the measurement data Db at the end time of the reporting period in March. In this example, the report data generation unit 143 calculates the difference between the activation count of 30,000 at 0:00 on March 1 and the activation count of 31000 at 0:00 on April 1 as 1000. The report data generation unit 143 sets the calculated value as the value of the element of the measurement data Db of the report data D3.

Next, the operation of the remote monitoring device 13 will be described with reference to FIG.
FIG. 4 is a flowchart showing an example of the operation of the remote monitoring device according to the first embodiment.

  In step S101, the first storage unit 131 updates the stored operation data based on the received state data. After that, the operation of the remote monitoring device 13 proceeds to step S102.

  In step S102, the generation unit 132 determines whether the current time is the switching time of the reporting period. If the determination result is Yes, the operation of the remote monitoring device 13 proceeds to step S103. If the determination result is No, the operation of the remote monitoring device 13 proceeds to step S104.

  In step S103, the generation unit 132 generates reproduction data. Then, the second storage unit 133 updates the stored reproduction data based on the reproduction data received from the generation unit 132. After that, the operation of the remote monitoring device 13 proceeds to step S104.

  In step S104, the transmission unit 134 determines whether the data request signal has been received. If the determination result is No, the operation of the remote monitoring device 13 proceeds to step S101. If the determination result is Yes, the operation of the remote monitoring device 13 proceeds to step S105.

  In step S105, the transmission unit 134 transmits the reproduction data to the data acquisition device 14. After that, the operation of the remote monitoring device 13 proceeds to step S101.

Next, the operation of the data acquisition device 14 will be described with reference to FIG.
FIG. 5 is a flowchart showing an example of the operation of the data acquisition device according to the first embodiment.

  In step S201, the data acquisition unit 141 selects one elevator 2 from the unselected list. The unselected list is a list of elevators 2 that have not been selected yet. After that, the data acquisition unit 141 removes the selected elevator 2 from the unselected list. Then, the operation of the data acquisition device 14 proceeds to step S202.

  In step S202, the data acquisition unit 141 determines whether the current time is the data acquisition time of the selected elevator 2 based on the data acquisition table. If the determination result is Yes, the operation of the data acquisition device 14 proceeds to step S203. If the determination result is No, the operation of the data acquisition device 14 proceeds to step S205.

  In step S203, the data acquisition unit 141 transmits a data request signal to the remote monitoring device 13 corresponding to the selected elevator 2. After that, the data acquisition unit 141 waits until it receives the reproduction data from the remote monitoring device 13. Then, the operation of the data acquisition device 14 proceeds to step S204.

  In step S204, the data acquisition unit 141 reproduces the operation data at the switching time of the selected reporting period of the elevator 2 based on the received reproduction data. After that, the operation data storage unit 142 stores the operation data reproduced by the data acquisition unit 141. Then, the operation of the data acquisition device 14 proceeds to step S205.

  In step S205, the report data generation unit 143 determines whether the current time is the report data generation time of the selected elevator 2 based on the data acquisition table. If the determination result is Yes, the operation of the data acquisition device 14 proceeds to step S206. If the determination result is No, the operation of the data acquisition device 14 proceeds to step S207.

  In step S206, the report data generation unit 143 generates report data. Then, the operation of the data acquisition device 14 proceeds to step S207.

  In step S207, the data acquisition unit 141 determines whether all the elevators 2 have been selected, for example, depending on whether the unselected list is empty. If the determination result is No, the operation of the data acquisition device 14 proceeds to step S201. If the determination result is Yes, the operation of the data acquisition device 14 proceeds to step S208.

  In step S208, the report data generation unit 143 resets the unselected list by returning all the elevators 2 to the unselected list based on the data acquisition table, for example. Then, the operation of the data acquisition device 14 proceeds to step S201.

  As described above, the data acquisition system 1 according to the first embodiment includes the plurality of remote monitoring devices 13 and the data acquisition device 14. Each of the plurality of remote monitoring devices 13 stores the operation data of the corresponding elevator 2 while updating it. Each of the plurality of remote monitoring devices 13 stores the reproduction data. The reproduction data is data for reproducing the operation data at the switching time of the reporting period after the switching time. The data acquisition device 14 acquires the reproduction data from each of the plurality of remote monitoring devices 13 at different times after the switching time.

  The reproduction data is generated by each of the plurality of remote monitoring devices 13 at the same time without communication with the data acquisition device 14. On the other hand, communication of the reproduction data is performed at different times for each of the plurality of remote monitoring devices 13. Accordingly, the data acquisition device 14 can distribute the communication for obtaining the operation data of the same reporting period to the plurality of remote monitoring devices 13 at different times. The data acquisition system 1 does not need to communicate at the same time to obtain the driving data at the same time. Therefore, the data acquisition system 1 can obtain operation data at the same time without adding a communication device to perform communication at the same time.

  The reproduction data is generated without communication with the data acquisition device 14. As a result, the data acquisition device 14 can obtain the driving data at the designated time regardless of the communication status.

  Further, each of the plurality of remote monitoring devices 13 stores the operation data at the switching time as reproduction data.

  The second storage unit 133 stores the same reproduction data as the operation data at the switching time. Accordingly, the data acquisition unit 141 can easily reproduce the operation data by copying, for example.

  The control panel 11 may function as a storage device instead of the remote monitoring device 13 or in cooperation with the remote monitoring device 13. The storage device may be provided separately from the control panel 11 and the remote monitoring device 13.

  Some or all of the plurality of elevators 2 may be provided in the same building 3.

  The report period, the data acquisition time, and the report data generation time stored in the remote monitoring device 13 and the data acquisition device 14 may be changed by a remote signal or a direct operation such as a maintenance person.

  The reporting period of a part of the plurality of elevators 2 may be different from that of another part of the plurality of elevators 2. The reporting period can be longer or shorter than January.

  The report data may be generated by an operation such as a maintenance staff. The report data generation time may be the same for some or all of the elevators 2.

Next, an example of the hardware configuration of the data acquisition system 1 will be described with reference to FIG.
FIG. 6 is a diagram showing a hardware configuration of a main part of the data acquisition system according to the first embodiment.

  Each function of the data acquisition system 1 can be realized by a processing circuit. The processing circuit includes at least one processor 1b and at least one memory 1c. The processing circuit may include at least one dedicated hardware 1a together with or as a substitute for the processor 1b and the memory 1c.

  When the processing circuit includes the processor 1b and the memory 1c, each function of the data acquisition system 1 is realized by software, firmware, or a combination of software and firmware. At least one of software and firmware is described as a program. The program is stored in the memory 1c. The processor 1b realizes each function of the data acquisition system 1 by reading and executing the program stored in the memory 1c.

  The processor 1b is also called a CPU (Central Processing Unit), a processing device, a computing device, a microprocessor, a microcomputer, or a DSP. The memory 1c is configured by a nonvolatile or volatile semiconductor memory such as RAM, ROM, flash memory, EPROM, EEPROM, etc., a magnetic disk, a flexible disk, an optical disk, a compact disk, a mini disk, a DVD, etc.

  When the processing circuit includes the dedicated hardware 1a, the processing circuit is realized by, for example, a single circuit, a composite circuit, a programmed processor, a parallel programmed processor, an ASIC, an FPGA, or a combination thereof.

  Each function of the data acquisition system 1 can be realized by a processing circuit. Alternatively, each function of the data acquisition system 1 can be collectively realized by a processing circuit. Part of each function of the data acquisition system 1 may be realized by dedicated hardware 1a, and the other part may be realized by software or firmware. In this way, the processing circuit realizes each function of the data acquisition system 1 by the hardware 1a, software, firmware, or a combination thereof.

Embodiment 2.
In the second embodiment, points different from the example disclosed in the first embodiment will be described in detail. As for the features not described in the second embodiment, any of the features disclosed in the first embodiment may be adopted.

FIG. 7 is a diagram showing an example of data in the data acquisition system according to the second embodiment.
In FIG. 7, a case where the report data for March is generated for the elevator E2 in FIG. 2 will be described as an example.

  The transmission unit 134 of the remote monitoring device 13 is connected to the first storage unit 131 so that the operation data can be acquired. The transmission unit 134 is connected to the second storage unit 133 so that the reproduction data can be acquired. The transmission unit 134 is connected to the data acquisition device 14 through the communication line 15 so as to transmit the operation data and the reproduction data.

  The data acquisition unit 141 of the data acquisition device 14 is connected to each of the plurality of remote monitoring devices 13 through the communication line 15 so that the operation data and the reproduction data can be received based on the data acquisition table.

  The generation unit 132 of the remote monitoring device 13 acquires the measurement data Db of the operation data D1 from the first storage unit 131 at 0:00 on March 1. 0:00 on March 1st is the end time of the reporting period in February and the starting time of the reporting period in March. The generation unit 132 generates the reproduction data D2 by copying the acquired measurement data Db. The reproduction data D2 generated by the generation unit 132 is the same as the measurement data Db of the operation data D1 at 0:00 on March 1st. The generation unit 132 transmits the reproduction data D2 to the second storage unit 133.

  The second storage unit 133 stores the reproduction data D2. The second storage unit 133 updates the stored reproduction data D2 by overwriting with the reproduction data D2 received from the generation unit 132. During the reporting period of March, the second storage unit 133 stores the reproduction data D2 that is the same as the measurement data Db of the operation data D1 at 0:00 on March 1.

  The data acquisition unit 141 of the data acquisition device 14 transmits a data request signal to the remote monitoring device 13 corresponding to the elevator E2 at 3:00 on March 10. 3:00 on March 10th is the data acquisition time associated with the elevator E2 by the data acquisition table.

  When the data request signal is received, the transmission unit 134 of the remote monitoring device 13 acquires the reproduction data D2 from the second storage unit 133. The transmission unit 134 transmits the operation data D1 and the reproduction data D2 to the data acquisition unit 141.

  The data acquisition unit 141 extracts elements associated with the time before 0:00 on March 1 from the acquired history data Da of the operation data D1. The data acquisition unit 141 generates history data Da based on the extracted elements. The data acquisition unit 141 generates the measurement data Db by copying the acquired reproduction data D2. The data acquisition unit 141 reproduces the operation data D1 at 0:00 on March 1 by the generated history data Da and measurement data Db. The data acquisition unit 141 transmits the reproduced operation data D1 to the operation data storage unit 142.

  The operation data storage unit 142 stores the received operation data D1 at the end time of the reporting period of February.

  As described above, each of the plurality of remote monitoring devices 13 according to the second embodiment stores measurement data and history data as operation data. The element values of the measurement data change due to the update. The history data is added with an element associated with the time by updating. Each of the plurality of remote monitoring devices 13 stores the measurement data at the switching time of the reporting period as reproduction data.

  The second storage unit 133 stores the same measurement data as the operation data at the switching time. Accordingly, the data acquisition unit 141 can easily reproduce the measurement data of the operation data by copying, for example. Elements of historical data are associated with times. Therefore, the data acquisition unit 141 can reproduce the driving data at the switching time from the driving data at the current time. Therefore, the reproduction data can be composed only of data for reproducing the measurement data. This reduces the storage capacity required for the second storage unit 133.

Embodiment 3.
In the third embodiment, points different from the examples disclosed in the first or second embodiment will be described in detail. As for the features not described in the third embodiment, any of the features disclosed in the first embodiment or the second embodiment may be adopted.

The function of the data acquisition system 1 will be described with reference to FIG.
FIG. 8 is a diagram showing an example of data in the data acquisition system according to the third embodiment.
In FIG. 8, a case where the report data for March is generated for the elevator E2 in FIG. 2 will be described as an example.

  The generator 132 of the remote monitoring device 13 is connected to the control panel 11 so as to receive the status data. The generation unit 132 is connected to the second storage unit 133 so that the reproduction data can be updated by the received state data.

  The generation unit 132 resets the reproduction data at 0:00 on March 1. The generation unit 132 resets the history data of the reproduction data by emptying the element. The generation unit 132 resets the measurement data of the reproduction data by setting the element value to 0, for example. 0:00 on March 1st is the end time of the reporting period in February and the starting time of the reporting period in March.

  When receiving the state data representing an abnormal or modulation event, the generation unit 132 adds a code representing the event in association with the time when the event occurred as an element of the history data Da of the reproduction data D2. When receiving the state data indicating the start-up of the hoisting machine 9, the generation unit 132 adds 1 to the element value of the measurement data Db of the reproduction data D2 indicating the number of times the hoisting machine 9 has been started. The generation unit 132 generates the reproduction data D2 from the history data Da and the measurement data Db. The generation unit 132 transmits the reproduction data D2 to the second storage unit 133.

  The second storage unit 133 stores the reproduction data D2. The second storage unit 133 updates the stored reproduction data D2 by overwriting with the reproduction data D2 received from the generation unit 132. During the reporting period of March, the second storage unit 133 stores the reproduction data D2 while updating the reproduction data D2 with the same change as the operation data D1 from 0:00 on March 1 as a base point. That is, the reproduction data D2 represents the difference between the operation data at 0:00 on March 1 and the operation data at the current time.

  The data acquisition unit 141 of the data acquisition device 14 transmits a data request signal to the remote monitoring device 13 corresponding to the elevator E2 at 3:00 on March 10. 3:00 on March 10th is the data acquisition time associated with the elevator E2 by the data acquisition table.

  When the data request signal is received, the transmission unit 134 of the remote monitoring device 13 acquires the reproduction data D2 from the second storage unit 133. The transmission unit 134 transmits the operation data D1 and the reproduction data D2 to the data acquisition unit 141.

  The data acquisition unit 141 reproduces the operation data D1 at 0:00 on March 1 by pulling back the difference represented by the reproduction data D2 from the operation data D1. The data acquisition unit 141 pulls back the history data Da by extracting an element included in the history data Da of the operation data D1 and not included in the history data Da of the reproduction data D2. In this example, the data acquisition unit 141 extracts an element that represents the event A that occurred on February 25 and an element that represents an event that occurred at a time before that. The data acquisition unit 141 pulls back the measurement data Db by subtracting the value of the element of the measurement data Db of the reproduction data D2 from the value of the element of the measurement data Db of the operation data D1. In this example, the data acquisition unit 141 subtracts the number of activations 300 in the reproduction data D2 from the number of activations 30300 in the operation data D1 to return the measurement data Db to 30,000. The data acquisition unit 141 transmits the reproduced operation data D1 to the operation data storage unit 142.

  At the data acquisition time of this example, the history data Da of the operation data D1 has an element representing the event B that occurred on March 2. The history data Da of the reproduction data D2 has an element that represents the event B that occurred on March 2, and an element that represents the event that occurred at a time earlier than that. As described above, the number of elements of the history data Da of the reproduction data D2 is smaller than the number of elements of the history data Da of the operation data D1. That is, the reproduction data D2, which is the difference data, has a smaller number of elements for which storage capacity needs to be secured than the operation data D1.

  At the data acquisition time of this example, the value of the element indicating the number of times of starting the measurement data Db of the operation data D1 is 30,300 times. 30300 is an information amount of 15 bits or more as an unsigned integer. The value of the element indicating the number of times of starting the measurement data Db of the reproduction data D2 is 300 times. 300 is an information amount of 9 bits or more as an unsigned integer. As described above, the number of bits required to represent the measurement data Db of the reproduction data D2 is smaller than the number of bits required to represent the measurement data Db of the operation data D1. That is, the reproduction data D2, which is the difference data, has a smaller number of bits required to secure the storage capacity than the operation data D1.

  The operation data storage unit 142 stores the received operation data D1 at the end time of the reporting period of February.

Next, the operation of the remote monitoring device 13 will be described with reference to FIG.
FIG. 9 is a flowchart showing an example of the operation of the remote monitoring device according to the third embodiment.

  In step S301, the first storage unit 131 updates the stored operation data based on the received state data. Then, the generation unit 132 generates reproduction data based on the received state data. Then, the second storage unit 133 updates the stored reproduction data based on the reproduction data received from the generation unit 132. After that, the operation of the remote monitoring device 13 proceeds to step S302.

  In step S302, the generation unit 132 determines whether the current time is the switching time of the reporting period. If the determination result is Yes, the operation of the remote monitoring device 13 proceeds to step S303. If the determination result is No, the operation of the remote monitoring device 13 proceeds to step S304.

  In step S303, the generation unit 132 resets the reproduction data. After that, the operation of the remote monitoring device 13 proceeds to step S304.

  In step S304, the transmission unit 134 determines whether the data request signal has been received. If the determination result is No, the operation of the remote monitoring device 13 proceeds to step S301. If the determination result is Yes, the operation of the remote monitoring device 13 proceeds to step S305.

  In step S305, the transmission unit 134 transmits the operation data and the reproduction data to the data acquisition device 14. After that, the operation of the remote monitoring device 13 proceeds to step S301.

  As described above, each of the plurality of remote monitoring devices 13 according to the third embodiment updates and stores the difference between the operation data at the switching time of the reporting period and the operation data at the current time as the reproduction data. .

  The second storage unit 133 stores data representing a difference as reproduction data. This reduces the storage capacity required for the second storage unit 133.

Fourth Embodiment
In the fourth embodiment, points different from the examples disclosed in the first to third embodiments will be described in detail. As for the features not described in the fourth embodiment, any features of the examples disclosed in the first to fourth embodiments may be adopted.

The function of the data acquisition system 1 will be described with reference to FIG.
FIG. 10 is a diagram showing an example of data in the data acquisition system according to the fourth embodiment.
In FIG. 10, the case of generating report data for March for the elevator E2 in FIG. 2 will be described as an example.

  The generation unit 132 of the remote monitoring device 13 resets the history data of the reproduction data D2 at 0:00 on March 1. The generation unit 132 acquires the measurement data Db of the operation data D1 from the first storage unit 131. 0:00 on March 1st is the end time of the reporting period in February and the starting time of the reporting period in March.

  When receiving the state data representing an abnormal or modulation event, the generation unit 132 adds a code representing the event in association with the time when the event occurred as an element of the history data Da of the reproduction data D2. The generation unit 132 generates the measurement data Db of the reproduction data D2 by copying the acquired measurement data Db. The generation unit 132 generates the reproduction data D2 from the history data Da and the measurement data Db. The generation unit 132 transmits the reproduction data D2 to the second storage unit 133.

  The second storage unit 133 stores the reproduction data D2. The second storage unit 133 updates the stored reproduction data D2 by overwriting with the reproduction data D2 received from the generation unit 132. During the reporting period of March, the second storage unit 133 stores the same measurement data Db as the operation data D1 at 0:00 on March 1 as a part of the reproduction data D2. During the reporting period of March, the second storage unit 133 updates the history data Da of the reproduction data D2 with the same change as the history data Da of the operation data D1 from 0:00 on March 1 as a base point. While remembering. That is, the history data Da of the reproduction data D2 represents the difference between the history data of the operation data at 0:00 on March 1 and the history data of the operation data at the current time.

  The data acquisition unit 141 of the data acquisition device 14 transmits a data request signal to the remote monitoring device 13 corresponding to the elevator E2 at 3:00 on March 10. 3:00 on March 10th is the data acquisition time associated with the elevator E2 by the data acquisition table.

  When receiving the data request signal, the transmission unit 134 of the remote monitoring device 13 acquires the operation data D1 from the first storage unit 131. The transmission unit 134 acquires the reproduction data D2 from the second storage unit 133. The transmission unit 134 transmits the operation data D1 and the reproduction data D2 to the data acquisition unit 141.

  The data acquisition unit 141 reproduces the operation data D1 at 0:00 on March 1 by the operation data D1 and the reproduction data D2. The data acquisition unit 141 transmits the reproduced operation data D1 to the operation data storage unit 142.

  The operation data storage unit 142 stores the received operation data D1 at the end time of the reporting period of February.

  As described above, each of the plurality of remote monitoring devices 13 according to the fourth embodiment stores measurement data and history data as operation data. The element values of the measurement data change due to the update. Elements are added to the history data by updating. Each of the plurality of remote monitoring devices 13 stores the measurement data at the switching time of the reporting period as a part of the reproduction data. Each of the plurality of remote monitoring devices 13 stores the difference between the history data at the switching time and the history data at the current time while updating it as another part of the reproduction data.

  The second storage unit 133 stores data representing a difference between history data as a part of the reproduction data. This reduces the storage capacity required for the second storage unit 133. The second storage unit 133 stores the same measurement data as the operation data at the switching time. Accordingly, the data acquisition unit 141 can easily reproduce the measurement data of the operation data by copying, for example.

Embodiment 5.
In the fifth embodiment, points different from the examples disclosed in the first to fourth embodiments will be described in detail. As for the features not described in the fifth embodiment, any of the features disclosed in the first to fifth embodiments may be adopted.

The function of the data acquisition system 1 will be described with reference to FIG.
FIG. 11 is a diagram showing an example of data in the data acquisition system according to the fifth embodiment.
In FIG. 11, the case of generating report data for March for the elevator E2 in FIG. 2 will be described as an example.

  The generation unit 132 of the remote monitoring device 13 resets the reproduction data D2 at 0:00 on March 1. 0:00 on March 1st is the end time of the reporting period in February and the starting time of the reporting period in March.

  When the state data indicating the start-up of the hoisting machine 9 is received, the generation unit 132 generates the reproduction data by adding 1 to the value of the element of the reproduction data D2 indicating the number of times the hoisting machine 9 has been started. To do. The generation unit 132 transmits the reproduction data D2 to the second storage unit 133.

  The second storage unit 133 stores the reproduction data D2. The second storage unit 133 updates the stored reproduction data D2 by overwriting with the reproduction data D2 received from the generation unit 132. During the reporting period of March, the second storage unit 133 stores the reproduction data D2 while updating the reproduction data D2 with the same change as the measurement data Db of the operation data D1 from 0:00 on March 1 as a base point. . That is, the reproduction data D2 represents the difference between the measurement data of the operation data at 0:00 on March 1 and the measurement data of the operation data at the current time.

  The data acquisition unit 141 of the data acquisition device 14 transmits a data request signal to the remote monitoring device 13 corresponding to the elevator E2 at 3:00 on March 10. 3:00 on March 10th is the data acquisition time associated with the elevator E2 by the data acquisition table.

  When receiving the data request signal, the transmission unit 134 of the remote monitoring device 13 acquires the operation data D1 from the first storage unit 131. The transmission unit 134 acquires the reproduction data D2 from the second storage unit 133. The transmission unit 134 transmits the operation data D1 and the reproduction data D2 to the data acquisition unit 141.

  The data acquisition unit 141 reproduces the operation data D1 at 0:00 on March 1 by the operation data D1 and the reproduction data D2. The data acquisition unit 141 transmits the reproduced operation data D1 to the operation data storage unit 142.

  The operation data storage unit 142 stores the received operation data D1 at the end time of the reporting period of February.

  As described above, each of the plurality of remote monitoring devices 13 according to the fifth embodiment stores measurement data and history data as operation data. The element values of the measurement data change due to the update. The history data is added with an element associated with the time by updating. Each of the plurality of remote monitoring devices 13 stores the difference between the measurement data at the switching time of the reporting period and the measurement data at the current time as reproduction data while updating it.

  The second storage unit 133 stores data representing the difference between the measurement data as the reproduction data. This reduces the storage capacity required for the second storage unit 133. Elements of historical data are associated with times. Therefore, the data acquisition unit 141 can reproduce the driving data at the switching time from the driving data at the current time. Therefore, the reproduction data can be composed only of data for reproducing the measurement data. As a result, the storage capacity required for the second storage unit 133 becomes smaller.

  The data acquisition system according to the present invention can be applied to a plurality of elevators that communicate operation data.

  1 data acquisition system, 1a hardware, 1b processor, 1c memory, 2 elevators, 3 buildings, 4 hoistways, 5 halls, 6 hall doors, 7 cages, 8 balancing weights, 9 hoisting machines, 10 main ropes, 11 control panel, 12 car door, 13 remote monitoring device, 14 data acquisition device, 15 communication line, 131 first storage unit, 132 generation unit, 133 second storage unit, 134 transmission unit, 141 data acquisition unit, 142 operation data Storage unit, 143 Report data generation unit

The elevator data acquisition system according to the present invention stores the elevator operation data while updating each, and each reproduces the reproduction data for reproducing the operation data at the switching time of the same reporting period after the switching time. A plurality of storage devices to be stored, and a data acquisition device that acquires the reproduction data from each of the plurality of storage devices at different times after the switching time and reproduces the operation data at the switching time .

The elevator data acquisition system according to the present invention stores the elevator operation data while updating each, and each reproduces the reproduction data for reproducing the operation data at the switching time of the same reporting period after the switching time. comprising a plurality of storage devices for storing, obtains the reproduction data at different times after the switching time from each of the plurality of storage devices, a data acquisition device for reproducing the operating data in the switching time, a plurality of storage Each of the devices updates and stores the difference between the operation data at the switching time and the operation data at the current time as reproduction data.
The elevator data acquisition system according to the present invention stores the elevator operation data while updating each, and each reproduces the reproduction data for reproducing the operation data at the switching time of the same reporting period after the switching time. A plurality of storage devices that store the data, and a data acquisition device that acquires the reproduction data from each of the plurality of storage devices at different times after the switching time and reproduces the operation data at the switching time. Each of the devices stores the measurement data in which the value of the element changes by the update and the history data in which the element is added by the update as the operation data, and the measurement data at the switching time is stored as a part of the reproduction data, and the switching time is stored. The difference between the historical data at the current time and the historical data at the current time is stored while being updated as another part of the reproduction data. That.
The elevator data acquisition system according to the present invention stores the operation data of the elevator while updating each, and each has the reproduction data for reproducing the operation data at the switching time of the same reporting period after the switching time. A plurality of storage devices that store the data, and a data acquisition device that acquires the reproduction data from each of the plurality of storage devices at different times after the switching time and reproduces the operation data at the switching time. Each of the devices stores, as operation data, measurement data in which the value of an element changes by updating and history data in which an element associated with time is added by updating, and stores the measurement data at the switching time and the measurement data at the current time. The difference is stored as the reproduction data while being updated.

Claims (6)

A plurality of storage devices, each of which stores operation data of the elevator while updating, and each of which stores reproduction data for reproducing the operation data at the switching time of the reporting period after the switching time,
A data acquisition device that acquires the reproduction data from each of the plurality of storage devices at different times after the switching time,
Elevator data acquisition system equipped with.   The elevator data acquisition system according to claim 1, wherein each of the plurality of storage devices stores operation data at the switching time as the reproduction data.   Each of the plurality of storage devices stores, as operation data, measurement data in which an element value changes by updating and history data in which an element associated with time is added by updating, and the measurement data at the switching time is reproduced. The elevator data acquisition system according to claim 1, wherein the elevator data acquisition system stores the data as use data.   The elevator data acquisition system according to claim 1, wherein each of the plurality of storage devices stores the difference between the operation data at the switching time and the operation data at the current time while updating the difference as reproduction data.   Each of the plurality of storage devices stores, as operation data, measurement data in which an element value changes by updating and history data in which an element is added by updating, and the measurement data at the switching time is part of the reproduction data. The data acquisition system for an elevator according to claim 1, wherein the difference between the history data at the switching time and the history data at the current time is stored while being updated as another part of the reproduction data.   Each of the plurality of storage devices stores, as operation data, measurement data in which an element value changes by updating and history data in which an element associated with time is added by updating, and the measurement data at the switching time and the current time are stored. The elevator data acquisition system according to claim 1, wherein the difference between the measured data and the measured data is stored as the reproduction data while being updated.

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