JPWO2020075223A1 - Elevator start count measuring device, elevator start count measurement system and elevator start count measurement method - Google Patents

Abstract

The present invention relates to an elevator start count measuring device (12) that can measure the number of starts of an elevator (2) that does not output necessary information from the control panel, an elevator start count measurement system (1), and an elevator start count measurement method. The purpose is to provide. The activation count measuring device (12) moves integrally with the car (8). The activation count measuring device (12) acquires the running information of the car (8). The start-up count measuring device (12) measures the start-up count of the elevator (2) based on the acquired travel information of the car (8).

Description

The present invention relates to an elevator start count measuring device, an elevator start count measuring system, and an elevator start count measuring method.

Patent Document 1 describes an example of an elevator start count measuring device. The activation count measuring device measures the activation count of the elevator corresponding to the departure floor and the arrival floor.

Japanese Patent Application Laid-Open No. 5-170385

However, the start-up count measuring device described in Patent Document 1 measures the start-up count of the elevator based on the information acquired from the control panel of the elevator. Therefore, the start-up count measuring device cannot measure the start-up count for an elevator that does not output necessary information from the control panel.

The present invention has been made to solve such a problem. An object of the present invention is to provide an elevator start count measuring device, an elevator start count measuring system, and an elevator start count measuring method that can measure the number of starts of an elevator that does not output necessary information from a control panel.

The elevator start count measuring device according to the present invention has a mounting portion attached to the elevator car, a measuring section that moves together with the car by the mounting portion, and acquires information on the running of the car, and a car acquired by the measuring section. It is provided with a counting unit that measures the number of times the elevator is started based on the traveling information of the elevator.

The elevator start count measurement system according to the present invention is attached to an elevator car, moves integrally with the car, acquires information on the running of the car, and based on the acquired information on the running of the car, the number of times the elevator is started. It is provided with a start-up count measuring device for measuring the number of start-ups and a terminal device for acquiring information on the number of start-ups of the elevator measured by the start-up count measuring device.

The method for measuring the number of times the elevator is started according to the present invention is to move together with the elevator car before a predetermined measurement period, acquire information on the running of the car, and based on the acquired information on the running of the car, the elevator. The installation process of attaching the start-up count measuring device to the car and the collection of the information on the number of elevator start-ups in the measurement period measured by the start-up count measuring device after the measurement period are acquired from the start-up count measuring device It has a process.

According to these inventions, the activation count measuring device moves integrally with the cage. The activation count measuring device acquires information on the running of the car. The start-up count measuring device measures the number of start-ups of the elevator based on the acquired car driving information. As a result, the number of activations can be measured even for an elevator that does not output necessary information from the control panel.

It is a block diagram of the activation number measurement system which concerns on Embodiment 1. FIG. It is a block diagram of the activation number measuring apparatus which concerns on Embodiment 1. FIG. It is a figure which shows the example of the measurement of the start-up count by the start-up count measuring apparatus which concerns on Embodiment 1. FIG. It is a flowchart which shows the example of the operation of the activation number measuring apparatus which concerns on Embodiment 1. It is a figure which shows the hardware configuration of the main part of the activation number measuring apparatus which concerns on Embodiment 1. FIG.

A mode for carrying out the present invention will be described with reference to the accompanying drawings. In each figure, the same or corresponding parts are designated by the same reference numerals, and duplicate description will be appropriately simplified or omitted.

Embodiment 1.
FIG. 1 is a configuration diagram of the activation number measurement system according to the first embodiment.

The activation count measurement system 1 is applied to the elevator 2.

The elevator 2 is provided in the building 3. Building 3 has a plurality of floors. In the elevator 2, the hoistway 4 penetrates each floor of the building 3.

The elevator 2 includes a hoisting machine 5, a main rope 6, a balance weight 7, a car 8, and a control panel (not shown). The hoisting machine 5 is provided in, for example, a hoistway 4. The hoisting machine 5 includes a motor and a sheave. The motor of the hoisting machine 5 is a device that generates a driving force. The sheave of the hoisting machine 5 is a device that rotates by a driving force generated by a motor. The main rope 6 is wound around the sheave of the hoisting machine 5. The main rope 6 is a member that moves following the rotation of the sheave of the hoisting machine 5. One end of the main rope 6 is provided in, for example, a car 8. The other end of the main rope 6 is provided on, for example, the balance weight 7. The balancing weight 7 is a device that balances the load applied to both sides of the sheave of the hoisting machine 5 with the car 8 through the main rope 6. The car 8 is a device for transporting a user or the like between a plurality of floors of the building 3 by traveling in the vertical direction inside the hoistway 4 following the movement of the main rope 6. The car 8 includes a car door 9. The car door 9 is a device that opens and closes so that the user can get on and off the car 8 when the car 8 is stopped on any of a plurality of floors. The control panel is a device that controls the operation of the elevator 2. The operation of the elevator 2 includes the running of the car 8. The control panel is provided, for example, in the hoistway 4.

In the elevator 2, the landing 10 is provided on each floor of the building 3. The landing 10 leads to the hoistway 4 by the landing entrance / exit. The landing entrance / exit is an opening connecting the landing 10 and the hoistway 4. The elevator 2 includes a landing door 11. The landing door 11 is provided at the landing entrance / exit. The landing door 11 is a device that opens and closes in conjunction with the car door 9 so that the user can get on and off the car 8.

In the maintenance of the elevator 2, the life of the main rope 6 is calculated. The life of the main rope 6 is used, for example, to determine when to replace the main rope 6. The life of the main rope 6 can be affected by wear and fatigue due to contact between the main rope 6 and the sheave of the hoisting machine 5, for example. Therefore, the life of the main rope 6 is calculated based on, for example, the number of times the elevator 2 is started. The number of times the elevator 2 is activated is measured, for example, as one time when the car 8 stopped on the departure floor stops on the arrival floor after traveling on the hoistway 4. The departure floor is one of several floors. The arrival floor is one of the plurality of floors that is different from the departure floor.

Alternatively, the life of the main rope 6 is calculated based on, for example, the number of times the elevator 2 is started in the main direction from the main floor. The main floor is one floor predetermined in the elevator 2. The main floor is, for example, the entrance floor where many users of the elevator 2 are used. The main floor is, for example, the first floor. The main direction is the traveling direction of the car 8 predetermined in the elevator 2. The main direction is, for example, a direction that users often use from the main floor. When the main floor is the first floor, the main direction is, for example, upward.

The activation number measurement system 1 includes an activation number measurement device 12. In this example, the control panel of the elevator 2 does not have a function of outputting information necessary for measuring the number of activations from the main floor to the main direction. At this time, the activation number measuring device 12 is applied to the elevator 2. The start-up count measuring device 12 is a device that measures the start-up count of the elevator 2. The activation number measuring device 12 is provided, for example, on the outer upper part of the car 8. In this example, the activation count measuring device 12 is not connected to the control panel of the elevator 2. The activation number measuring device 12 includes a case 13 and a measuring unit 14.

The case 13 forms the outer shell of the activation number measuring device 12. The case 13 is attached to the outside of the car 8. The case 13 is mounted on, for example, the upper beam of the car 8. The upper beam of the car 8 is made of a metal material containing, for example, iron. The upper beam of the car 8 is provided on the outside of the car 8. The case 13 includes a magnet 15. The magnet 15 is provided on the bottom surface of the case 13. The magnet 15 is attached to the outside of the car 8 by magnetic force. The magnet 15 is an example of a mounting portion. The case 13 is attached by a magnet 15 so as to be able to move integrally with the car 8.

The measuring unit 14 is housed in the case 13. The measuring unit 14 is provided so as to be able to move integrally with the car 8 by the magnet 15 of the case 13. The measuring unit 14 is a device for acquiring travel information of the car 8. The measuring unit 14 includes an accelerometer 16 and an altimeter 17.

The accelerometer 16 is a device for measuring acceleration. The acceleration measured by the accelerometer 16 is the acceleration of the car 8. The acceleration measured by the accelerometer 16 is an example of running information of the car 8 acquired by the measuring unit 14.

The altimeter 17 is a device for measuring the altitude in the hoistway 4. The altimeter 17 is, for example, a barometric altimeter that calculates altitude based on the absolute pressure measured by a barometric pressure sensor. The altimeter 17 is a radio altimeter that calculates the distance to the target by measuring the reflection time from the target using radio waves, for example. The target is, for example, the ceiling of the hoistway 4. The altimeter 17 may calculate the altitude based on the distance to the target. The altitude in the hoistway 4 is, for example, the altitude from the lower end of the hoistway 4. The altitude measured by the altimeter 17 corresponds to the position of the car 8. The altitude measured by the altimeter 17 is an example of running information of the car 8 acquired by the measuring unit 14.

When the car 8 is stopped on any floor, the activation count measuring device 12 is located at an altitude corresponding to the floor. For example, when the car 8 is stopped on the first floor, the activation count measuring device 12 is located at the altitude H1 corresponding to the first floor. When the car 8 is stopped on the second floor, the activation count measuring device 12 is located at the altitude H2 corresponding to the second floor.

The activation count measuring device 12 stores the altitude range corresponding to each of the plurality of floors. The activation count measuring device 12 stores the altitude range R1 including the altitude H1 as the altitude range corresponding to, for example, the first floor. The activation count measuring device 12 stores the altitude range R2 including the altitude H2 as the altitude range corresponding to, for example, the second floor.

Subsequently, the configuration of the activation number measuring device 12 will be described with reference to FIG.
FIG. 2 is a configuration diagram of the activation number measurement device according to the first embodiment.

The start-up count measuring device 12 includes a counting unit 18, a storage unit 19, an external terminal 20, a battery 21, a power switch 22, a measurement mode switch 23, an altimeter initial setting switch 29, and a display device 24. Be prepared.

The counting unit 18 is housed in the case 13. The counting unit 18 is a unit that measures the number of times the elevator 2 is started based on the travel information of the car 8 acquired by the measuring unit 14.

The storage unit 19 is housed in the case 13. The storage unit 19 is a unit that stores information on the number of times the elevator 2 is started, which is measured by the counting unit 18. The storage unit 19 is an external storage medium such as an SD card. At this time, the case 13 has a slot on the outer surface for connecting the external storage media.

The external terminal 20 is provided on the outer surface of the case 13. The external terminal 20 is a terminal capable of receiving an electric power supply for operating the activation number measuring device 12 from an external power source. The external terminal 20 is a terminal capable of communicating information with an external device. The external terminal 20 is, for example, a USB (Universal Serial Bus) socket.

The battery 21 is housed in the case 13. The battery 21 is a storage battery that supplies electric power to operate the activation count measuring device 12 when the external terminal 20 is not supplied with electric power from an external power source. The battery 21 is connected to the external terminal 20 so that the external terminal 20 is charged by the electric power received from the outside.

The power switch 22 is provided on the outer surface of the case 13. The power switch 22 is a switch that operates the activation number measuring device 12 when it is in the ON state.

The measurement mode switch 23 is provided on the outer surface of the case 13. The measurement mode switch 23 is a switch for switching the operation mode of the activation number measurement device 12. The activation number measuring device 12 measures the number of activations of the elevator 2 when the operation mode is the measurement mode. The activation number measurement device 12 accepts a setting for measuring the number of activations of the elevator 2, for example, when the operation mode is the standby mode.

The altimeter initial setting switch 29 is a switch that calibrates the altitude measured by the altimeter 17 when the start count measuring device 12 is installed in the car 8 to the altitude of the floor on which the car 8 is stopped. The floor on which the car 8 is stopped is selected, for example, by the number of times the altimeter initialization switch 29 is pressed within a predetermined time. For example, when the activation count measuring device 12 is installed while the car 8 is stopped on the second floor, the altimeter 17 measures when the altimeter initial setting switch 29 is pressed twice within a predetermined time. The altitude is calibrated to the altitude H2 corresponding to the second floor.

The display device 24 is provided on the case 13. The display device 24 is, for example, a plurality of LED (Light Emitting Diode) lamps. The display device 24 includes, for example, a "power" lamp indicating that the start-up count measuring device 12 is operating. The display device 24 includes, for example, a "normal / abnormal" lamp indicating whether or not the activation count measuring device 12 is operating normally. The display device 24 includes a "battery capacity low" lamp indicating that the capacity of the battery 21 is low. The display device 24 includes, for example, a “measuring” lamp indicating that the operation mode of the activation number measuring device 12 is the measurement mode.

The startup count measurement system 1 includes a conversion adapter 25, a terminal device 26, and a maintenance server 27. The conversion adapter 25 or the terminal device 26 is connected to the external terminal 20 of the activation count measuring device 12. The activation number measurement device 12 may be provided with a plurality of external terminals 20 so that the conversion adapter 25 and the terminal device 26 can be individually connected.

The conversion adapter 25 is a device that converts the electric power supplied from the external power source and supplies it to the activation number measuring device 12. The conversion adapter 25 is, for example, an AC (Alternating Current) adapter that converts alternating current power from a commercial power source into direct current power. The conversion adapter 25 is connected to, for example, an outlet provided on the outer upper part of the car 8.

The terminal device 26 is a device in which dedicated software corresponding to the activation count measuring device 12 is installed. The terminal device 26 is, for example, a personal computer. The dedicated software is, for example, software that sets the activation count measuring device 12 and processes information on the activation count.

The maintenance server 27 is connected to the terminal device 26 through the network 28. The maintenance server 27 is a server that manages maintenance information of the elevator 2 and other elevators. The maintenance server 27 is provided outside the building 3, for example. The maintenance information includes, for example, maintenance result and maintenance plan information. The maintenance result information includes, for example, information on the number of startups. The maintenance plan information includes, for example, information on the timing of maintenance, the content of maintenance, and whether or not maintenance is performed.

Subsequently, the method of measuring the number of times the elevator 2 is started will be described with reference to FIG.

First, the maintenance staff sets the activation count measuring device 12 by the dedicated software before measuring the activation count of the elevator 2. At this time, the activation count measuring device 12 is connected to the maintenance terminal by the external terminal 20. The power switch 22 is in the ON state. The operation mode of the activation number measuring device 12 is the standby mode. The maintenance staff starts the connection between the activation count measuring device 12 and the terminal device 26 by using the dedicated software. The maintenance staff sets, for example, the COM port of the terminal device 26 to which the activation count measuring device 12 is connected. The activation number measuring device 12 is operated by the electric power supplied from the terminal device 26.

The maintenance staff sets the measurement of the activation count measuring device 12 by using the dedicated software. Measurement settings include main floor and main direction settings. Measurement settings include setting measurement parameters and setting the current time. The setting of the measurement parameters includes the setting of the altitude Hn corresponding to each floor of the building 3 and the range Rn including the altitude Hn. Here, the altitude Hn corresponds to the nth floor of the building 3. The range Rn includes altitude Hn. At this time, the maintenance personnel may make settings by registering and calling default setting values. The maintenance staff disconnects the connection between the activation count measuring device 12 and the terminal device 26 by using the dedicated software. The power switch 22 is switched to the OFF state.

Next, the maintenance staff performs the work of the mounting process. The mounting process is carried out, for example, with the car 8 stopped on the first floor. In the installation process, the maintenance staff places the activation count measuring device 12 on the upper beam of the car 8. The activation number measuring device 12 is attached to the upper beam of the car 8 by the magnetic force of the magnet 15. The activation number measuring device 12 is connected to an outlet provided on the outer upper part of the car 8 through a conversion adapter 25 by an external terminal 20. At this time, the power switch 22 is in the ON state. The maintenance staff presses the altimeter initial setting switch 29 once within a predetermined time. As a result, the altitude measured by the altimeter 17 is calibrated to the altitude H1 corresponding to the first floor. The operation mode of the activation number measuring device 12 is switched to the measuring mode. The activation number measuring device 12 is operated by the electric power supplied from the conversion adapter 25.

In the subsequent measurement period, the elevator 2 operates normally. The measurement period is a period for measuring the number of times the elevator 2 is started. The measurement period is, for example, a predetermined period of 2 weeks or more. During the measurement period, the car 8 travels between a plurality of floors in response to a call from the user.

At this time, the measuring unit 14 of the activation number measuring device 12 moves integrally with the car 8. The accelerometer 16 of the measuring unit 14 measures the acceleration. The measuring unit 14 acquires the acceleration measured by the accelerometer 16 as running information of the car 8. The altimeter 17 measures the altitude in the hoistway 4. The measuring unit 14 acquires the altitude measured by the altimeter 17 as travel information of the car 8.

The counting unit 18 measures the number of times the elevator 2 is started based on the travel information of the car 8 acquired by the measuring unit 14. The counting unit 18 determines whether the elevator 2 has been started based on the acceleration measured by the accelerometer 16. When determining that the elevator 2 has been activated, the counting unit 18 determines which floor each of the departure floor and the arrival floor was based on the altitude measured by the altimeter 17. The counting unit 18 measures the number of times the elevator 2 is activated for each group of the departure floor and the arrival floor. The counting unit 18 adds once to the number of times the elevator 2 is activated for each set of the determined departure floor and arrival floor. In particular, when the departure floor is the main floor and the arrival floor is the floor in the main direction from the departure floor, the counting unit 18 determines the number of times the elevator 2 is activated from the main floor to the main floor. Add once.

The storage unit 19 stores the number of times the elevator 2 is activated measured by the counting unit 18. The storage unit 19 stores, for example, the number of times the elevator 2 is activated for each group of the departure floor and the arrival floor. The storage unit 19 stores, for example, the number of times the elevator 2 is activated from the main floor to the main direction. The number of times the elevator 2 is activated, which is stored in the storage unit 19, is updated every time, for example, the counting unit 18 determines that the elevator 2 has been activated.

After the measurement period has elapsed, the maintenance personnel perform the work of the collection process. In the collection process, the maintenance staff collects the activation number measuring device 12 from above the upper beam of the car 8. The operation mode of the activation number measuring device 12 is switched to the standby mode. The power switch 22 is switched to the OFF state.

In the collection step, the activation count measuring device 12 is connected to the terminal device 26 by the external terminal 20. At this time, the power switch 22 is in the ON state. The operation mode of the activation number measuring device 12 is the standby mode. In the collection process, the maintenance staff acquires information on the number of times the elevator 2 is activated, which is stored in the storage unit 19, by using dedicated software.

Next, the maintenance staff processes the acquired information on the number of times the elevator 2 is started by using the dedicated software. The maintenance staff erases the information on the number of times the elevator 2 is activated from the storage unit 19. The maintenance staff saves the acquired information. The maintenance personnel may print the acquired information by using the dedicated software. The maintenance personnel may convert the data format of the acquired information by the dedicated software. The data format is, for example, a CSV (Comma-Separated Values) format.

The maintenance personnel may add unique information to the acquired information. The unique information is information unique to the measurement of the acquired information. The unique information is, for example, the identification number of the elevator 2 that has measured the number of times of activation, the name of the building 3 in which the elevator 2 is provided, the measurement period, and the like.

The terminal device 26 may convert the acquired information on the number of times the elevator 2 is activated into information on the number of times corresponding to the measurement period of the standard length by the dedicated software. The standard length measurement period is, for example, 2 weeks. The terminal device 26 performs conversion by, for example, multiplying the acquired number of activations by the ratio of the length of the actual measurement period to the length of the standard measurement period.

The terminal device 26 transmits the information processed by the dedicated software to the maintenance server 27.

The maintenance server 27 calculates the life of the main rope 6 based on the number of times the elevator 2 is activated, which is included in the received information. In particular, when the received information includes the number of times the elevator 2 is activated from the main floor to the main direction, the maintenance server 27 calculates the life of the main rope 6 based on the number of times. The maintenance server 27 stores the calculated life of the main rope 6 as, for example, maintenance result information.

The maintenance server 27 updates the maintenance plan when it receives information from the terminal device 26. For example, the maintenance server 27 registers that the measurement of the number of startups has been completed as maintenance plan information. The maintenance server 27 registers, for example, the timing of measuring the next number of startups as maintenance plan information. The maintenance server 27 may set the timing of measuring the next number of activations based on the calculated life of the main rope 6.

Subsequently, an example of measuring the number of activations by the activation number measuring device 12 will be described with reference to FIG.
FIG. 3 is a diagram showing an example of measuring the number of activations by the activation number measuring device according to the first embodiment.

In the graph G, an example of the time change of the acceleration of the car 8 when the car 8 stopped on the departure floor stops on the arrival floor after traveling on the hoistway 4 is shown. The horizontal axis of the graph G represents time. The vertical axis of the graph G represents the acceleration in the same direction as the traveling direction of the car 8. That is, when the car 8 travels upward, the vertical axis of the graph G represents the acceleration with the upward direction positive. When the car 8 travels downward, the vertical axis of the graph G represents the acceleration with the downward direction positive.

The car 8 stopped on the departure floor starts traveling upward, for example, in response to a call from the user.

After that, the acceleration of the car 8 increases in the positive direction. The counting unit 18 determines whether the magnitude of the acceleration in the positive direction of the car 8 exceeds the magnitude of the positive threshold value. A positive threshold is a predetermined value of acceleration. Positive thresholds are examples of measurement parameters. When the magnitude of the acceleration in the positive direction of the car 8 exceeds the magnitude of the positive threshold value, the counting unit 18 indicates whether the state in which the acceleration exceeds the positive threshold value continues for longer than the acceleration continuation determination time. To judge. The acceleration continuation determination time is a predetermined time. The acceleration continuation determination time is an example of measurement parameters.

After that, the magnitude of the acceleration of the car 8 becomes smaller. The car 8 travels toward the arrival floor at a constant speed.

After that, the acceleration of the car 8 increases in the negative direction. The counting unit 18 determines whether the magnitude of the acceleration in the negative direction of the car 8 exceeds the magnitude of the negative threshold value. The negative threshold is a predetermined acceleration value. Negative thresholds are examples of measurement parameters. When the magnitude of the acceleration in the negative direction of the car 8 exceeds the magnitude of the negative threshold value, the counting unit 18 indicates whether the state in which the acceleration exceeds the negative threshold value continues for longer than the deceleration continuation determination time. To judge. The deceleration continuation determination time is a predetermined time. The deceleration continuation determination time is an example of measurement parameters.

After that, the magnitude of the acceleration of the car 8 becomes smaller. The car 8 stops on the arrival floor.

In the counting unit 18, after the magnitude of the positive acceleration continuously exceeds the magnitude of the positive threshold value for longer than the acceleration continuation determination time, the magnitude of the negative acceleration decelerates the magnitude of the negative threshold value for a deceleration continuation determination time. It is determined that the elevator 2 has been activated when the threshold value is continuously exceeded for a longer period of time. At this time, the counting unit 18 adds 1 time to the number of times the elevator 2 is started.

When determining that the elevator 2 has been activated, the counting unit 18 determines which of the plurality of floors each of the departure floor and the arrival floor was based on the altitude measured by the altimeter 17.

The activation count measuring device 12 stores the altitude range corresponding to each of the plurality of floors. The counting unit 18 determines the floor corresponding to the range including the altitude of the altimeter 17 immediately before the elevator 2 is activated as the departure floor. The counting unit 18 determines the floor corresponding to the range including the altitude of the altimeter 17 immediately after the elevator 2 is started and then stopped as the arrival floor. When the departure floor is the main floor and the direction from the departure floor to the arrival floor is the main direction, the counting unit 18 determines that the elevator 2 has been activated from the main floor to the main direction.

For example, when the altitude of the altimeter 17 immediately before the elevator 2 is activated is included in the range R1, the counting unit 18 determines that the first floor is the departure floor. When the altitude of the altimeter 17 immediately after the elevator 2 is started and then stopped is included in the range R2, the counting unit 18 determines that the second floor is the arrival floor. In this example, the main floor is the first floor. The main direction is upward. At this time, the counting unit 18 determines that the elevator 2 has started from the main floor in the main direction. The counting unit 18 adds 1 time to the number of times the elevator 2 is started from the main floor to the main direction.

The altitude range to which each of the floors corresponds is an example of a measurement parameter.

Subsequently, an example of the operation of the activation number measuring device 12 will be described with reference to FIG.
FIG. 4 is a flowchart showing an example of the operation of the activation number measuring device according to the first embodiment.

In step S1, the activation count measuring device 12 accepts the measurement setting. After that, the operation of the activation number measuring device 12 proceeds to step S2.

In step S2, the counting unit 18 determines whether the elevator 2 has been activated. When the determination result is No, the operation of the activation number measuring device 12 proceeds to step S2 again. When the determination result is Yes, the operation of the activation number measuring device 12 proceeds to step S3.

In step S3, the counting unit 18 determines the departure floor and the arrival floor. After that, the operation of the activation number measuring device 12 proceeds to step S4.

In step S4, the counting unit 18 adds 1 time to the number of times the elevator 2 is started. The counting unit 18 adds once to the number of times the elevator 2 is activated for each group on the departure floor and the arrival floor. When the departure floor is the main floor and the direction from the departure floor to the arrival floor is the main direction, the counting unit 18 adds 1 to the number of times the elevator 2 is started from the main floor to the main direction. To do. After that, the operation of the activation number measuring device 12 proceeds to step S2.

As described above, the activation number measuring device 12 according to the first embodiment includes a magnet 15, a measuring unit 14, and a counting unit 18. The magnet 15 is attached to the car 8 of the elevator 2. The measuring unit 14 moves integrally with the car 8 by the magnet 15. The measuring unit 14 acquires the traveling information of the car 8. The counting unit 18 measures the number of times the elevator 2 is started based on the travel information of the car 8 acquired by the measuring unit 14.

Further, the activation number measurement system 1 according to the first embodiment includes an activation number measurement device 12 and a terminal device 26. The activation number measuring device 12 is attached to the car 8 of the elevator 2. The activation number measuring device 12 moves integrally with the car 8. The activation number measuring device 12 acquires the running information of the car 8. The start-up count measuring device 12 measures the start-up count of the elevator 2 based on the acquired travel information of the car 8. The terminal device 26 acquires information on the number of activations of the elevator 2 measured by the activation number measuring device 12.

Further, the method for measuring the number of activations according to the first embodiment includes a mounting step and a collecting step. In the mounting process, the start-up count measuring device 12 is mounted on the car 8 prior to the predetermined measurement period. In the collection step, after the measurement period, the information on the number of activations of the elevator 2 in the measurement period measured by the activation number measurement device 12 is acquired from the activation number measurement device 12.

The activation number measuring device 12 moves integrally with the car 8. The activation number measuring device 12 acquires the running information of the car 8. The start-up count measuring device 12 measures the start-up count of the elevator 2 based on the acquired travel information of the car 8. As a result, the number of activations can be measured even for the elevator 2 that does not output necessary information from the control panel.

The activation count measuring device 12 does not acquire information from the control panel of the elevator 2. By exercising integrally with the car 8, the activation number measuring device 12 directly acquires the running information of the car 8 from the movement of the car 8. As a result, the start-up count measuring device 12 can measure the start-up count regardless of the model of the elevator 2.

The maintenance staff can acquire information on the number of times the elevator 2 has been started by installing and collecting the number of times the elevator 2 has been started at the site. This simplifies the work of measuring the number of activations.

Further, the measuring unit 14 includes an accelerometer 16 for measuring the acceleration. The measuring unit 14 acquires the acceleration measured by the accelerometer 16 as traveling information of the car 8.

The measuring unit 14 moves integrally with the car 8 to directly acquire information on the acceleration of the car 8 from the movement of the car 8. As a result, the measuring unit 14 can acquire the acceleration information of the car 8 without relying on the information from the control panel of the elevator 2. The measuring unit 14 can determine the activation of the elevator 2 without depending on the information from the control panel of the elevator 2.

Further, the counting unit 18 continuously decelerates the magnitude of the negative threshold after the magnitude of the positive acceleration continuously exceeds the magnitude of the positive threshold for longer than the acceleration continuation determination time. If the determination time is continuously exceeded for a longer period of time, one is added to the number of times the elevator 2 is started. The positive acceleration is the acceleration in the same direction as the traveling direction of the car 8 measured by the accelerometer 16. The negative acceleration is the acceleration in the direction opposite to the traveling direction of the car 8 measured by the accelerometer 16.

The counting unit 18 measures the start of the elevator 2 when observing the time change of the acceleration peculiar to the start of the elevator 2. The car 8 may vibrate when the user gets on and off the car 8. Further, when the car 8 is stopped at a position deviated from a plurality of floors in maintenance work or the like, the car 8 may be operated at a low speed. The counting unit 18 prevents the start of the elevator 2 from being measured by an acceleration that is not caused by such a normal start of the elevator 2. As a result, the accuracy of measuring the number of times the elevator 2 is started is improved.

Further, the measuring unit 14 includes an altimeter 17 for measuring the altitude in the hoistway 4 of the elevator 2. The measuring unit 14 acquires the altitude measured by the altimeter 17 as travel information of the car 8.

The measuring unit 14 moves integrally with the car 8 to directly acquire information on the position of the car 8 from the movement of the car 8. As a result, the measuring unit 14 can acquire the information on the position of the car 8 without relying on the information from the control panel of the elevator 2.

Further, the counting unit 18 determines the floor on which the car 8 is stopped based on the altitude measured by the altimeter 17.

When determining that the elevator 2 has been activated, the counting unit 18 determines which floor each of the departure floor and the arrival floor was based on the altitude measured by the altimeter 17. The counting unit 18 can determine the floor on which the car 8 is stopped without relying on the information from the control panel of the elevator 2.

Further, the counting unit 18 measures the number of times the elevator 2 is activated for each group of the departure floor and the arrival floor.

The life of the main rope 6 can be calculated from the frequency with which each part of the main rope 6 comes into contact with the sheave of the hoisting machine 5. The portion where the main rope 6 contacts the sheave of the hoisting machine 5 is determined by the departure floor and the arrival floor. Therefore, the life of the main rope 6 is accurately calculated by the number of times the elevator 2 is activated for each group of the departure floor and the arrival floor. In this way, the activation count measuring device 12 can acquire information for calculating the life of the main rope 6 with higher accuracy.

Further, the counting unit 18 measures the number of times the elevator 2 is started from the main floor to the main direction.

The life of the main rope 6 is mainly affected by the most deteriorated part of the main rope 6. The portion of the main rope 6 where deterioration is likely to proceed is a portion that frequently contacts the sheave of the hoisting machine 5. That is, the life of the main rope 6 is accurately calculated by the number of times of activation from the main floor, which is frequently used, in the main direction. The number of activations from the main floor to the main direction is represented by a single number. Therefore, a simple calculation formula can be used in calculating the life of the main rope 6 based on the number of activations from the main floor to the main direction. In this way, the activation count measuring device 12 can acquire information for calculating the life of the main rope 6 more easily and with higher accuracy.

Even if the elevator 2 is equipped with a device for measuring the number of activations, the device measures the number of activations by a relay signal or the like that is excited and degaussed only once when the elevator 2 is activated. Sometimes. At this time, the number of activations measured by the device is the number of activations regardless of the departure floor and the direction of travel. Even in such an elevator 2, the number of activations from the main floor to the main direction can be measured without depending on the information from the control panel.

Further, the magnet 15 is attached to the outside of the car 8 by magnetic force.

As a result, the maintenance staff can attach the activation number measuring device 12 simply by placing it on the upper beam of the car 8, for example. This makes the work of measuring the number of activations easier. Further, the activation number measuring device 12 is attached to the outside of the car 8. As a result, malfunctions caused by, for example, the user accidentally touching the activation number measuring device 12 are suppressed.

Further, the startup count measurement system 1 includes a maintenance server 27. The maintenance server 27 manages maintenance information including a maintenance plan. The maintenance server 27 updates the maintenance plan when it receives information from the terminal device 26. The terminal device 26 transmits the acquired information on the number of times the elevator 2 is activated to the maintenance server 27.

Information on the number of times the elevator 2 has been started is transmitted to the maintenance server 27. As a result, the information is collectively managed together with the information of other elevators. Therefore, maintenance information becomes easy to manage. Further, the maintenance plan is updated to the maintenance server 27 by communicating the information on the number of times the elevator 2 is started. Therefore, the work load of the maintenance staff is reduced in the maintenance of the elevator 2.

The activation number measurement device 12 may be, for example, a general-purpose mobile terminal equipped with a measurement application. The mobile terminal is, for example, a smartphone. At this time, the smartphone is equipped with a case including, for example, a magnet 15. The measuring unit 14 may acquire the acceleration and altitude measured by the acceleration sensor and the altitude sensor of the smartphone as the traveling information of the car 8.

Further, when the car 8 is stopped on any of the plurality of floors, the measuring unit 14 may calibrate the altitude of the activation number measuring device 12 to the altitude corresponding to the floor.

Further, the measuring unit 14 may obtain the altitude of the activation number measuring device 12 by, for example, double integrating the time change of the acceleration obtained by the accelerometer 16. As a result, the measuring unit 14 can calculate the altitude of the car 8 without providing an altimeter.

Further, the measuring unit 14 may obtain the acceleration of the activation number measuring device 12 by, for example, second-order differentiation of the time change of the altitude obtained by the altimeter 17. Further, the counting unit 18 may determine that the elevator 2 has been started due to the change in altitude obtained by the altimeter 17 in a predetermined time. For example, the counting unit 18 determines that the elevator 2 has started when the altitude measured by the altimeter 17 changes by 500 mm or more within 3 seconds. Further, the counting unit 18 may determine that the elevator 2 has stopped when the change in altitude obtained by the altimeter 17 during a predetermined time is less than a predetermined value. For example, after determining that the elevator 2 has started, the counting unit 18 determines that the elevator 2 has stopped when the change in altitude obtained by the altimeter 17 for, for example, 3 seconds is less than 100 mm. As a result, the counting unit 18 can detect the start and stop of the elevator 2 without providing an accelerometer.

Further, the measuring unit 14 may calibrate the measured value of the other by one of the accelerometer 16 and the altimeter 17. For example, when the measured value of the altimeter 17 fluctuates even though the acceleration is not detected by the accelerometer 16, the measuring unit 14 fluctuates the measured value of the altimeter 17 due to an external factor such as atmospheric pressure. May be determined. For example, when it is determined from the acceleration detected by the accelerometer 16 that the vehicle has stopped on the same floor, but the measured value of the altimeter 17 fluctuates, the measuring unit 14 externally measures the atmospheric pressure or the like. It may be determined that the measured value of the altimeter 17 fluctuates depending on the factor. At this time, the measuring unit 14 may calibrate the measured value of the altimeter 17, for example, by setting an offset or the like.

Further, the measuring unit 14 may include, for example, a speedometer for measuring the relative speed with respect to the inner wall of the hoistway 4 or the guide rail. The measuring unit 14 may acquire the speed measured by the speedometer as running information of the car 8.

Subsequently, an example of the hardware configuration of the startup count measuring device 12 will be described with reference to FIG.
FIG. 5 is a diagram showing a hardware configuration of a main part of the activation number measuring device according to the first embodiment.

Each function of the activation number measuring device 12 can be realized by a processing circuit. The processing circuit includes at least one processor 12b and at least one memory 12c. The processing circuit may include at least one dedicated hardware 12a with or as a substitute for the processor 12b and the memory 12c.

When the processing circuit includes the processor 12b and the memory 12c, each function of the activation count measuring device 12 is realized by software, firmware, or a combination of software and firmware. At least one of the software and firmware is written as a program. The program is stored in the memory 12c. The processor 12b realizes each function of the activation count measuring device 12 by reading and executing the program stored in the memory 12c.

The processor 12b is also referred to as a CPU (Central Processing Unit), a processing device, an arithmetic unit, a microprocessor, a microcomputer, and a DSP. The memory 12c is composed of, for example, a non-volatile or volatile semiconductor memory such as RAM, ROM, flash memory, EPROM, EEPROM, a magnetic disk, a flexible disk, an optical disk, a compact disk, a mini disk, a DVD, or the like.

When the processing circuit includes dedicated hardware 12a, 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 activation count measuring device 12 can be realized by a processing circuit. Alternatively, each function of the activation count measuring device 12 can be collectively realized by a processing circuit. For each function of the startup count measuring device 12, a part may be realized by the dedicated hardware 12a, and the other part may be realized by software or firmware. In this way, the processing circuit realizes each function of the boot count measuring device 12 by the hardware 12a, the software, the firmware, or a combination thereof.

The start-up count measuring device, the start-up count measuring system, and the start-up count measuring method according to the present invention can be applied to an elevator.

1 Start-up count measurement system, 2 Elevator, 3 Building, 4 Hoistway, 5 Hoisting machine, 6 Main rope, 7 Balance weight, 8 Car, 9 Car door, 10 Landing, 11 Landing door, 12 Start-up count measuring device , 13 case, 14 measuring unit, 15 magnet, 16 accelerometer, 17 altimeter, 18 counting unit, 19 storage unit, 20 external terminal, 21 battery, 22 power switch, 23 measurement mode switch, 24 display device, 25 conversion adapter, 26 terminal equipment, 27 maintenance server, 28 network, 29 altimeter initialization switch, 12a hardware, 12b processor, 12c memory

Elevator start count measuring device according to the present invention includes a case having a mounting portion attached to the car of the elevator, is housed in a case, a measurement unit moving in a cage integral, to obtain the information of the running of the car, the case It is provided with a counting unit that is stored in the elevator and measures the number of times the elevator is started based on the car running information acquired by the measuring unit.

The elevator activation count measuring system according to the present invention is attached to an elevator car by an outer case , moves integrally with the car, acquires information on the running of the car, and is based on the acquired information on the running of the car. It includes a start-up count measuring device that measures the number of times the elevator is started, and a terminal device that acquires information on the number of elevator start-ups measured by the start-up count measuring device.

The method for measuring the number of times the elevator is started according to the present invention is to move together with the elevator car before a predetermined measurement period, acquire information on the running of the car, and based on the acquired information on the running of the car, the elevator. The number of times the elevator is started is collected from the car, and the information on the number of times the elevator is started during the measurement period measured by the number of times of start-up measurement device is collected from the car. It includes a collection process acquired from the measuring device.

The elevator activation frequency measuring device according to the present invention includes a case having a mounting portion attached to the elevator car, a measuring unit housed in the case, moving integrally with the car, and acquiring information on the running of the car. It is equipped with a counting unit that measures the number of times the elevator is started based on the car running information acquired by the measuring unit, and the measuring unit is equipped with an accelerometer that measures acceleration and is measured by the accelerometer. The acceleration is acquired as the information on the running of the car, and the counting unit continuously exceeds the magnitude of the positive threshold value for longer than a predetermined time by the magnitude of the acceleration in the same direction as the running direction of the car. When the magnitude of acceleration in the direction opposite to the traveling direction of the car continuously exceeds the magnitude of the negative threshold value for longer than a predetermined time, one is added to the number of times the elevator is started.

The system for measuring the number of activations of an elevator according to the present invention is attached to an elevator car by an outer case, moves integrally with the car, acquires information on the running of the car, and is based on the acquired information on the running of the car. It is equipped with a start-up count measuring device that measures the number of times the elevator is started and a terminal device that acquires information on the number of elevator start-ups measured by the start-up count measuring device. The start-up count measuring device is an accelerometer that measures acceleration. The acceleration measured by the accelerometer is acquired as information on the running of the car, and the magnitude of the acceleration in the same direction as the running direction of the car continues the magnitude of the positive threshold value longer than a predetermined time. After exceeding, if the magnitude of acceleration in the direction opposite to the direction of travel of the car continuously exceeds the magnitude of the negative threshold for longer than a predetermined time, the number of times the elevator is started is once. Add .

The method for measuring the number of times the elevator is started according to the present invention has an accelerometer that moves integrally with the car of the elevator and measures the acceleration before a predetermined measurement period , and runs the car with the acceleration measured by the accelerometer. After the magnitude of acceleration in the same direction as the traveling direction of the car continuously exceeds the magnitude of the positive threshold for longer than a predetermined time, the direction opposite to the traveling direction of the car is obtained. When the magnitude of acceleration continuously exceeds the magnitude of the negative threshold for longer than a predetermined time, the number of times the elevator is started is measured by adding one to the number of times the elevator is started. The installation process of attaching the device to the car and the collection process of acquiring the information on the number of times the elevator is started during the measurement period measured by the start-up count measuring device after the measurement period from the start-up count measuring device collected from the car. Be prepared.

The elevator start count measuring device according to the present invention has a case having a mounting portion attached to the elevator car and a case housed in the case, and when the operation mode is the measurement mode, the car and the car move together to run the car. Based on the measuring unit that acquires the information and the running information of the car that is stored in the case and acquired by the measuring unit, the activation of the elevator, which is the information acquired by the external device when the operation mode is the standby mode . It is equipped with a counting unit that measures the number of times, the measuring unit is equipped with an accelerometer that measures acceleration, and the acceleration measured by the accelerometer is acquired as information on the running of the car, and the counting unit is the direction of running of the car. After the magnitude of acceleration in the same direction continuously exceeds the magnitude of the positive threshold for longer than a predetermined time, the magnitude of acceleration in the direction opposite to the direction of travel of the car is the magnitude of the negative threshold. Is continuously exceeded for a longer than a predetermined time, one is added to the number of times the elevator is started.

The elevator activation count measurement system according to the present invention is attached to the elevator car by an outer case, and when the operation mode is the measurement mode, the car and the car move together to acquire information on the running of the car. The start count measuring device that measures the number of times the elevator is started based on the driving information of the car and the information on the number of times the elevator is started measured by the start count measuring device are displayed in the standby mode as the operation mode of the start count measuring device. It is equipped with a terminal device to be acquired at a certain time , and the activation count measuring device is equipped with an accelerometer for measuring acceleration, and acquires the acceleration measured by the accelerometer as information on the running of the car, which is the same as the running direction of the car. After the magnitude of the acceleration in the direction continuously exceeds the magnitude of the positive threshold for longer than a predetermined time, the magnitude of the acceleration in the direction opposite to the direction of travel of the car exceeds the magnitude of the negative threshold. If the time is continuously exceeded for longer than the predetermined time, one is added to the number of times the elevator is started.

The method for measuring the number of times the elevator is started according to the present invention has an accelerometer that moves integrally with the elevator cage and measures the acceleration before a predetermined measurement period, and accelerates when the operation mode is the measurement mode. The acceleration measured by the meter is acquired as information on the running of the car, and after the magnitude of the acceleration in the same direction as the running direction of the car continuously exceeds the magnitude of the positive threshold for longer than a predetermined time, the car When the magnitude of acceleration in the direction opposite to the direction of travel exceeds the magnitude of the negative threshold continuously for longer than a predetermined time, one is added to the number of times the elevator is started to increase the number of times the elevator is started. The start-up count measuring device that measures the number of startups is attached to the car, and the operation mode of the start-up count measuring device is switched to the measurement mode. After the measurement period, the operation mode of the start-up count measuring device is switched to the standby mode and started. the number of times the measuring apparatus is recovered from the basket, comprises information for the number of elevator start of measurement period number of starts measuring device is measured, and a recovery step of acquiring the number of activations measuring apparatus recovered from the car, the.

Claims (11)

A mounting part that can be attached to the elevator car,
A measuring unit that moves integrally with the car by the mounting part and acquires information on the running of the car.
A counting unit that measures the number of times the elevator is started based on the vehicle running information acquired by the measuring unit.
Elevator activation count measuring device equipped with. The elevator activation frequency measuring device according to claim 1, wherein the measuring unit includes an accelerometer for measuring acceleration, and acquires the acceleration measured by the accelerometer as travel information of the car. After the magnitude of the acceleration in the same direction as the traveling direction of the car continuously exceeds the magnitude of the positive threshold value for a predetermined time, the counting unit is opposite to the traveling direction of the car. The activation of the elevator according to claim 2, wherein once is added to the number of activations of the elevator when the magnitude of the acceleration in the direction continuously exceeds the magnitude of the negative threshold value for longer than a predetermined time. Counting device. The elevator according to any one of claims 1 to 3, wherein the measuring unit includes an altimeter that measures the altitude in the hoistway of the elevator, and acquires the altitude measured by the altimeter as travel information of the car. Start-up count measuring device. The elevator activation frequency measuring device according to claim 4, wherein the counting unit determines the floor on which the car is stopped based on the altitude measured by the altimeter. The elevator activation count measuring device according to any one of claims 1 to 5, wherein the counting unit measures the number of elevator activations for each set of departure floor and arrival floor. The elevator activation count measuring device according to any one of claims 1 to 6, wherein the counting unit measures the number of times the elevator is activated from the main floor to the main direction. The elevator activation frequency measuring device according to any one of claims 1 to 7, wherein the mounting portion is magnetically mounted on the outside of the car. With a start-up count measuring device that is attached to the elevator car, moves integrally with the car, acquires running information of the car, and measures the number of times the elevator is started based on the acquired running information of the car. ,
A terminal device that acquires information on the number of times the elevator has been started measured by the start number measuring device, and
Elevator activation count measurement system equipped with. A maintenance server that manages maintenance information including a maintenance plan and updates the maintenance plan when receiving information from the terminal device is provided.
The elevator activation count measurement system according to claim 9, wherein the terminal device transmits the acquired information on the elevator activation count to the maintenance server. Prior to the predetermined measurement period, the elevator car and the car are moved together to acquire the running information of the car, and the number of times the elevator is started is measured based on the acquired running information of the car. The installation process of attaching the measuring device to the car and
After the measurement period, a collection step of acquiring information on the number of times the elevator is started during the measurement period measured by the start number measuring device from the start number measuring device, and
How to measure the number of times the elevator is started.

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