JP5834977B2 - Elevator car equipment - Google Patents

Description

  The present invention relates to an elevator car apparatus capable of performing various settings using a remote controller.

  The elevator apparatus is provided with switches for performing various settings on the operation panel of the car. That is, the elevator setting is determined by the contact position (ON position / OFF position) of this switch. For example, the ON / OFF state of the car lighting and the operation mode of the elevator can be switched to a desired state by setting the switch (contact point) to the ON position or the OFF position. The switch contact signal is input to the elevator control panel. The control panel recognizes and stores the current setting content based on the contact signal input from the switch.

  As a measure for eliminating the switch from the car operation panel, for example, an elevator can be set using a remote controller.

  Patent Document 1 below discloses a technique for a maintenance worker in an elevator hall to take data in a control panel into a maintenance terminal using wireless communication.

JP-A-11-263546

  When the elevator is set using a remote controller, the setting contents cannot be recognized by the contact position as when the setting is performed by a switch. For this reason, it is necessary to save the setting contents somewhere and to fetch the data from the storage destination as necessary.

If the data is stored in the control panel like the one described in Patent Document 1, the elevator system including the control panel needs to be repaired. For this reason, there is a problem that the cost for renovation is large and it is difficult to shift to a system using a remote controller.
Further, as described above, when the elevator is set using a remote controller, the set content cannot be recognized by the contact position as in the case where a switch is provided. For this reason, it is important to be able to easily restore the setting contents at the time of disappearance in consideration of the case where the data at the storage destination has disappeared.

  The remote controller is used in various elevator devices. For this reason, it is difficult to store the setting contents of various elevator apparatuses in the same remote controller.

  The present invention has been made to solve the above-described problems, and its purpose is to appropriately save and easily restore the setting contents when the elevator is set using a remote controller. It is another object of the present invention to provide an elevator car apparatus that can significantly reduce the labor and cost required for refurbishment even when it is necessary to refurbish the elevator by using a remote controller.

The elevator car apparatus according to the present invention includes: a receiving unit that receives a radio signal output from a predetermined remote controller; a setting unit that sets an elevator based on a signal received by the receiving unit; and a receiving unit Based on the received signal, the master board that stores the current setting contents of the elevator as remote control data in the first storage means, and connected to the master board by the in-panel communication means, and based on the data received from the master board, the elevator A slave board for storing the current setting contents as remote control data in the second storage means and a third storage means, connected to the master board by the in-board communication means, and based on the data received from the master board, the elevator Saves the current settings of the remote control as remote control data in the third storage means It includes a substrate, a storage dedicated substrate are those which waterproofing is applied.
The elevator car apparatus according to the present invention includes a receiving means for receiving a radio signal output from a predetermined remote controller, a setting means for setting the elevator based on the signal received by the receiving means, and a reception Based on the signal received by the means, based on the data received from the master board connected to the master board by the inboard communication means and the master board that stores the current setting contents of the elevator as remote control data in the first storage means , A slave board that stores the current setting contents of the elevator as remote control data in the second storage means, and a car operation panel provided with in-panel communication means, the car operation panel includes an indicator control board that controls the indicator, An announcement control board for controlling the speaker, a button control board for controlling the car button, Comprising at least two control boards, the master substrate is formed of a single control board car operating panel is provided, the slave board is made of other control board car operating panel is provided.

  With the elevator car apparatus according to the present invention, when the elevator setting is performed using a remote controller, the setting contents can be appropriately saved and easily restored. Further, even when the elevator needs to be repaired by using a remote controller, the labor and cost required for the repair can be greatly reduced.

It is a block diagram which shows the principal part of the elevator cab apparatus in Embodiment 1 of this invention. It is a flowchart which shows operation | movement of the elevator cab apparatus in Embodiment 1 of this invention.

  The present invention will be described in detail with reference to the accompanying drawings. In each drawing, the same or corresponding parts are denoted by the same reference numerals. The overlapping description is simplified or omitted as appropriate.

Embodiment 1 FIG.
FIG. 1 is a configuration diagram showing a main part of an elevator car apparatus according to Embodiment 1 of the present invention.

  The elevator apparatus according to the present embodiment has a function of performing various settings related to the elevator using the remote controller 1. The remote controller 1 outputs a radio signal using infrared rays. For example, the elevator setting that has been conventionally performed by the switch in the open door, such as switching on / off the car lighting or switching the operation mode, operates the remote controller 1 appropriately (appropriate signal from the remote controller 1). To send).

In FIG. 1, 2 is a car operation panel and 3 is a control panel.
The car operation panel 2 is provided inside the elevator car. The car operation panel 2 includes, for example, one unit device. The car operation panel 2 includes an indicator 4, an indicator control board 5, a speaker 6, an announcement control board 7, a car button 8, a button control board 9, and a storage dedicated board 10.

  Reference numeral 11 denotes in-board communication means, and 12 denotes outside-board communication means. The in-panel communication means 11 manages the communication function in the car operation panel 2. The off-board communication means 12 manages the communication function between the car operation panel 2 and external devices. The control panel 3 controls the operation of the entire elevator. The control panel 3 is disposed, for example, in a machine room or the like, and performs car running control, door opening / closing control, and the like. The car operation panel 2 communicates with the control panel 3 via the off-board communication means 12.

  The indicator 4 displays characters, symbols, etc., and notifies predetermined information to passengers in the car. The inge control board 5 has a function of controlling the indicator 4 (display thereof). The engine control board 5 includes, for example, a microprocessor 13 (hereinafter also simply referred to as “microcomputer 13”), a storage element 14 (storage means), and a light receiving element 15.

  Various data necessary for controlling the indicator 4 are stored in the storage element 14. For example, display data for performing predetermined display on the indicator 4 is stored in the storage element 14. The storage element 14 is composed of, for example, an EEPROM or a flash ROM. The storage element 14 may be built in the microcomputer 13.

  The light receiving element 15 constitutes a receiving unit that receives a radio signal output from the remote controller 1. When the light receiving element 15 receives a signal for performing a predetermined setting from the remote controller 1, the light receiving element 15 outputs the received signal (or a signal corresponding to the received signal) to the microcomputer 13.

  In the present embodiment, a configuration in which the light receiving element 15 is mounted on the engine control board 5 is shown. However, this configuration is merely an example. For example, the receiving means may be installed at a place other than the inge control board 5.

The microcomputer 13 performs predetermined control based on data stored in the storage element 14 and various input signals.
A signal output from the remote controller 1 is received by the light receiving element 15, and a corresponding signal is output from the light receiving element 15 to the microcomputer 13. When a predetermined signal is input from the light receiving element 15, the microcomputer 13 performs predetermined control according to a signal received by the light receiving element 15 (a signal transmitted from the remote controller 1).

  For example, the microcomputer 13 causes the indicator 4 to perform an appropriate answerback display based on the input signal from the light receiving element 15.

  Further, the microcomputer 13 has a function as a setting means for causing the control panel 3 or the like to set the elevator based on the signal received by the light receiving element 15. That is, the microcomputer 13 outputs a command to the control panel 3 or the like based on the input signal from the light receiving element 15 and causes each device to perform an operation according to the signal received by the light receiving element 15. For example, when a signal for switching the elevator operation from the normal mode to the maintenance mode is output from the remote controller 1, the microcomputer 13 instructs the operation mode to be switched based on the input signal from the light receiving element 15. Is output to the control panel 3. When the control panel 3 receives the command from the microcomputer 13, the control panel 3 switches the elevator operation from the normal mode to the maintenance mode.

  In the present embodiment, a configuration is shown in which the microcomputer 13 of the inge control board 5 has the function of setting means. However, this configuration is merely an example. For example, the car operation panel 2 may be provided with a board provided with the function of setting means separately from the inge control board 5.

  The storage element 14 stores the current setting contents of the elevator as remote control data (data indicating the contents set by the remote controller 1). The microcomputer 13 updates the remote control data stored in the storage element 14 based on the input signal from the light receiving element 15. That is, when a new signal is input from the light receiving element 15, the microcomputer 13 uses the new input signal (a signal newly received by the light receiving element 15 from the remote controller 1) as the remote control data stored in the storage element 14. Change to match. With this update function, the remote control data stored in the storage element 14 can always match the latest setting contents.

  When the light receiving element 15 receives a new signal and updates the remote control data of the storage element 14, the microcomputer 13 updates the remote control data (all or part (updated part)) after the announcement control board 7 and button control. The data is output to the substrate 9 and the storage dedicated substrate 10.

  The speaker 6 outputs sound and notifies predetermined information to passengers in the car. The announcement control board 7 has a function of controlling the speaker 6 (output). The announcement control board 7 includes, for example, a microprocessor 16 (hereinafter simply referred to as “microcomputer 16”) and a storage element 17 (storage means).

  The storage element 17 stores various data necessary for controlling the speaker 6. For example, message data for announcement from the speaker 6 is stored in the storage element 17. Further, the storage element 17 stores the current setting contents of the elevator as remote control data. The storage element 17 is composed of, for example, an EEPROM or a flash ROM. The storage element 17 may be built in the microcomputer 16.

The microcomputer 16 performs predetermined control based on data stored in the storage element 17 and various input signals.
A signal output from the remote controller 1 is received by the light receiving element 15, and a corresponding signal is output from the light receiving element 15 to the microcomputer 13. When a predetermined signal is input from the light receiving element 15, the microcomputer 13 updates the remote control data in the storage element 14 and outputs the updated data to the announcement control board 7.

  The microcomputer 16 updates the remote control data stored in the storage element 17 based on the update data received from the indicator control board 5 (microcomputer 13). That is, when the update data is input from the engine control board 5, the microcomputer 16 converts the remote control data stored in the storage element 17 into the update data (a signal newly received by the light receiving element 15 from the remote controller 1). Change to match. With this update function, the remote control data stored in the storage element 17 can be always matched with the latest setting contents.

  The car button 8 is a push button for operation by passengers in the car. The car button 8 includes, for example, a destination button for each destination floor, a door open button, and a door close button. The button control board 9 performs control related to the car button 8. The button control board 9 includes, for example, a microprocessor 18 (hereinafter also simply referred to as “microcomputer 18”) and a storage element 19 (storage means).

  The storage element 19 stores various data necessary for control related to the car button 8. For example, button arrangement data for specifying the arrangement of each button is stored in the storage element 19. In addition, the current setting contents of the elevator are stored in the storage element 19 as remote control data. The storage element 19 is composed of, for example, an EEPROM or a flash ROM. The storage element 19 may be built in the microcomputer 18.

The microcomputer 18 performs predetermined control based on data stored in the storage element 19 and various input signals.
A signal output from the remote controller 1 is received by the light receiving element 15, and a corresponding signal is output from the light receiving element 15 to the microcomputer 13. When a predetermined signal is input from the light receiving element 15, the microcomputer 13 updates the remote control data in the storage element 14 and outputs the updated data to the button control board 9.

  The microcomputer 18 updates the remote control data stored in the storage element 19 based on the update data received from the indicator control board 5 (microcomputer 13). That is, when update data is input from the engine control board 5, the microcomputer 18 converts the remote control data stored in the storage element 19 into the update data (a signal newly received by the light receiving element 15 from the remote controller 1). Change to match. With this update function, the remote control data stored in the storage element 19 can always match the latest setting contents.

  The storage dedicated substrate 10 is a dedicated small substrate for storing the current setting contents of the elevator as remote control data. Similarly to the announcement control board 7 and the button control board 9, the storage-dedicated board 10 is connected to the indicator control board 5 via the on-board communication means 11. The storage-only substrate 10 is incorporated in the car operation panel 2 in a state where it has been waterproofed. For this reason, even if the car operation panel 2 is submerged, the data stored in the storage dedicated substrate 10 is not destroyed. The storage-dedicated substrate 10 includes, for example, a microprocessor 20 (hereinafter simply referred to as “microcomputer 20”) and a storage element 21 (storage means).

  The storage element 21 stores the current setting contents of the elevator as remote control data. The storage element 21 is composed of, for example, an EEPROM or a flash ROM. The storage element 21 may be built in the microcomputer 20.

The microcomputer 20 performs predetermined control for matching the remote control data stored in the storage element 21 with the current setting contents of the elevator.
A signal output from the remote controller 1 is received by the light receiving element 15, and a corresponding signal is output from the light receiving element 15 to the microcomputer 13. When a predetermined signal is input from the light receiving element 15, the microcomputer 13 updates the remote control data in the storage element 14 and outputs the updated data to the storage dedicated substrate 10.

  The microcomputer 20 updates the remote control data stored in the storage element 21 based on the update data received from the indicator control board 5 (microcomputer 13). That is, when the update data is input from the engine control board 5, the microcomputer 20 converts the remote control data stored in the storage element 21 into the update data (a signal newly received by the light receiving element 15 from the remote controller 1). Change to match. With this update function, the remote control data stored in the storage element 21 can always match the latest setting contents.

  In the car operation panel 2 having the above configuration, the inge control board 5 is used as a master board for storing remote control data. The master board is connected to a plurality of slave boards via the in-board communication means 11. In the configuration shown in the present embodiment, the announcement control board 7, the button control board 9, and the storage dedicated board 10 correspond to the slave board.

  In the car operation panel 2, remote control data is distributed and stored on a plurality of internal substrates (storage elements). For this reason, even if the remote control data stored on some substrates (storage elements) disappears, the remote control data stored on other substrates (storage elements) is used to store the remote control data on the some substrates. Can be restored.

  For example, let us consider a case where a part of a board fails and is replaced with a new board. The remote control data of the new board is set to the initial value. In such a case, the remote control data of the new board is easily copied by copying the remote control data of the other board to the new board and without relying on an external device such as the control panel 3 (only in the internal processing of the car operation panel 2). Can be matched to the current setting of the elevator. In the example shown in FIG. 1, the indicator control board 5 (microcomputer 13) determines that the remote control data of the storage element 17 (or 19) does not match the remote control data of the storage element 14. The remote control data in the storage element 14 may be copied. Moreover, if the remote control data of the storage element 14 is the initial value, the inge control board 5 (the microcomputer 13) may copy the remote control data of the storage element 17 (or 19, 21) to the storage element 14.

  When the elevator car is submerged, the inge control board 5, the announcement control board 7, and the button control board 9 all break down. The car operation panel 2 having this configuration employs a storage-dedicated substrate 10 that is waterproofed as one of the slave substrates. For this reason, even when the car is submerged, the remote control data of the other board (master board and other slave boards) can be easily restored with the remote control data of the storage dedicated board 10 being positive.

  The configuration shown in FIG. 1 shows an example of a master substrate and a slave substrate. A substrate other than the inge control substrate 5 may be adopted as the master substrate. Further, only one substrate may be adopted as the slave substrate. The slave substrate may not include the storage dedicated substrate 10. Even with such a configuration, certain effects can be obtained.

Next, the consistency check function of the remote control data provided in the car operation panel 2 will be specifically described.
The consistency check function is a function for determining whether or not the remote control data of the master board and the remote control data of each slave board match the current setting contents of the elevator. The car operation panel 2 is also provided with an automatic recovery function for remote control data. This automatic recovery function is a function for automatically matching the remote control data of the board with the current setting contents when the remote control data of some boards does not match the current setting contents.

  FIG. 2 is a flowchart showing the operation of the elevator car apparatus according to Embodiment 1 of the present invention. FIG. 2 shows a processing flow when the consistency check function and the automatic recovery function are enabled when the car operation panel 2 is powered on. In the description of FIG. 2 and FIG. 2, among the boards having the remote control data storage function, boards other than the master board and the storage dedicated board 10 are referred to as slave boards. The processing flow shown in FIG. 2 is performed by, for example, a microcomputer mounted on each substrate.

  When the power of the car operation panel 2 is turned on (S1), each board incorporated in the car operation panel 2 is operated. Thereby, the infrared signal transmitted from the remote controller 1 can be received by the light receiving element 15, and the corresponding signal can be input to the master substrate.

  When the car operation panel 2 is turned on, the inge control board 5 (master board) checks whether or not the storage dedicated board 10 exists on the car operation board 2 (S2, S3). The engine control board 5 performs the determination of S3 by outputting a predetermined signal. That is, the inge control board 5 determines whether or not the storage dedicated board 10 exists based on the presence or absence of a reply from the board connected by the in-board communication means 11.

  For example, an ID is assigned in advance to each board incorporated in the car operation panel 2. The engine control board 5 identifies the presence / absence of the dedicated storage board 10 based on the presence / absence of a reply to the ID command. The inge control board 5 can also identify the presence / absence of a slave board and the number of slave boards, if any, based on the presence / absence of a reply to the ID command.

  If the return control board 5 cannot detect a reply to the ID command for the storage dedicated board 10, it determines that the storage dedicated board 10 does not exist in the car operation panel 2 (No in S3). In such a case, the inge control board 5 next checks whether there is a slave board on the car operation panel 2 (S4, S5). The inge control board 5 determines whether or not there is a slave board as well as whether or not there is a dedicated storage board 10.

  If the reply control board 5 cannot detect any reply to the slave board ID command, it determines that there is no slave board on the car operation panel 2 (No in S5). When the determination of No is made in both S3 and S5, no board is connected to the in-board communication means 11 when viewed from the ini control board 5. Such a state cannot be said to be normal. For this reason, if the Inge control board 5 determines No in S5, it detects a failure (NG) in the consistency check of the remote control data and resets the car operation panel 2 (S6).

  On the other hand, when the return control board 5 detects a reply to the ID command for the storage dedicated board 10 in S3, the inge control board 5 determines that the storage dedicated board 10 exists in the car operation panel 2 (Yes in S3). In this case, the inge control board 5 copies the remote control data stored in the storage dedicated board 10 to the storage element 14 via the in-board communication means 11 (S7). In the process of S7, it is desirable to incorporate a verification check as to whether or not the copying has been performed normally.

  When the remote control data of the dedicated storage board 10 is copied to the storage element 14, the engine control board 5 next checks whether or not a slave board exists in the car operation panel 2 (S8, S9). The processes of S8 and S9 are the same as the processes of S4 and S5.

  The inge control board 5 determines that there is no slave board on the car operation panel 2 if it cannot detect any reply to the ID command for the slave board (No in S9). In such a case, the inge control board 5 proceeds to the process of S6, and determines the failure (NG) of the consistency check of the remote control data.

  If the engine control board 5 can detect even one reply to the ID command for the slave board, it determines that there is a slave board on the car operation panel 2 (Yes in S9). In such a case, the inge control board 5 sends the remote control data stored in the storage element 14 to the storage elements of the slave board (for example, the storage element 17 of the announcement control board 7 and the button control board 9 via the in-board communication means 11. (S10). Also in the processing of S10, it is desirable to incorporate a verification check as to whether or not the copying has been performed normally.

  When the remote control data of the storage element 14 is copied to the storage elements 17 and 19, respectively, the indicator control board 5 detects the success (OK) of the consistency check of the remote control data (S11). As a result, the car operation panel 2 starts communication with the control panel 3 and operates with the normal function.

  On the other hand, the inge control board 5 determines that there is a slave board on the car operation panel 2 if it can detect even one reply to the ID command for the slave board in S5 (Yes in S5). In this case, the inge control board 5 performs consistency check between the remote control data stored in the master board and the remote control data stored in the slave board (S12).

  In the consistency check, the engine control board 5 first takes in the remote control data stored in the storage element 17 and the remote control data stored in the storage element 19 via the in-panel communication means 11. Then, the intake control board 5 determines whether or not the captured remote control data matches the remote control data stored in the storage element 14 (S13).

  If the remote control data stored in each slave board matches the remote control data stored in the inge control board 5 (No in S13), the indigo control board 5 has successfully checked the consistency of the remote control data ( OK) is detected (S11). As a result, the car operation panel 2 starts communication with the control panel 3 and operates with the normal function.

  If the remote control data stored in any of the slave boards does not match the remote control data stored in the inge control board 5, the inge control board 5 determines the matching NG for the remote control data of that slave board (S13). Yes)

  For example, let us consider a case where the remote control data of the Inge control board 5 is “0Ah”, the remote control data of the announcement control board 7 is “0Ah”, and the remote control data of the button control board 9 is “00h”. The remote control data of the announcement control board 7 matches the remote control data of the inge control board 5. For this reason, the inge control board 5 determines the matching OK for the remote control data of the announcement control board 7. On the other hand, the remote control data of the button control board 9 is an initial value and does not match the remote control data of the inge control board 5. Therefore, the inge control board 5 determines that the button control board 9 has been replaced with a new board, and determines the matching NG for the remote control data.

  When the matching NG is determined for any one of the slave boards in S13, the inge control board 5 transmits the remote control data stored in the storage element 14 to the slave board for which the matching NG is determined via the in-panel communication means 11. Copying is made to the storage element (in the above example, the storage element 19 of the button control board 9) (S14). Also in the processing of S14, it is desirable to incorporate a verification check as to whether or not the copying has been performed normally.

  When the remote control data of the storage element 14 is copied to the storage element of the slave board for which the matching NG is determined, the ini control board 5 detects the success (OK) of the consistency check of the remote control data (S11). As a result, the car operation panel 2 starts communication with the control panel 3 and operates with the normal function.

  In the elevator car apparatus having the above configuration, when the elevator setting is performed using the remote controller 1, the setting contents can be appropriately stored and easily restored. Also, the remote control data distributed storage function and automatic restoration function can be realized only in the internal processing of the car operation panel 2 without depending on external devices such as the control panel 3. For this reason, it is not necessary to make a major modification from the existing elevator apparatus, and the application of the elevator apparatus equipped with the infrared remote control system can be facilitated.

  The existing elevator apparatus is also provided with a board for controlling an indicator, a board for controlling a speaker, a board for controlling a car button, and the like on a car operation panel, and a memory element is mounted on each board. For this reason, if storage, writing, and reading of remote control data are performed using these storage elements, it is possible to cope with the change of the substrate itself to a minimum.

  In addition, when the board on which the remote control data is stored is replaced with a new board, the remote control data that matches the current setting of the elevator is stored in the storage element of the new board when the car operation panel 2 is turned on. . This eliminates the need to store remote control data before board replacement and to re-register the stored remote control data on a new board, thus greatly simplifying elevator maintenance.

DESCRIPTION OF SYMBOLS 1 Remote controller 2 Car operation panel 3 Control panel 4 Indicator 5 Inge control board 6 Speaker 7 Announcement control board 8 Car button 9 Button control board 10 Board | substrate for preservation | save 11 In-board communication means 12 External communication means 13, 16, 18, 20 Microprocessor (microcomputer)
14, 17, 19, 21 Memory element 15 Light receiving element

Claims (8)

Receiving means for receiving a radio signal output from a predetermined remote controller;
Setting means for setting the elevator based on the signal received by the receiving means;
Based on the signal received by the receiving means, a master board for storing the current setting contents of the elevator as remote control data in the first storage means,
A slave board connected to the master board by means of in-panel communication means, and based on the data received from the master board, the current setting contents of the elevator are stored as remote control data in the second storage means;
A third storage unit, connected to the master board by the in-panel communication unit, and based on data received from the master board, the current setting contents of the elevator are stored as remote control data in the third storage unit A dedicated storage board,
Equipped with a,
The storage-dedicated substrate is an elevator car device that is waterproofed .   When the remote control data stored in the first storage unit and the remote control data stored in the second storage unit do not match, the master board stores the master substrate in the second storage unit and the first storage unit. The elevator car apparatus according to claim 1, wherein the stored remote control data is stored.   2. The master board causes the first storage means to save remote control data saved in the second storage means when the remote control data saved in the first storage means is an initial value. Or the elevator car apparatus of Claim 2. The elevator car apparatus according to any one of claims 1 to 3, wherein the master board causes the first storage unit to store remote control data stored in the third storage unit when power is turned on. . The master substrate is stored in the first storage unit in the second storage unit after the remote control data stored in the third storage unit is stored in the first storage unit when the power is turned on. The elevator car apparatus according to claim 4 , wherein the remote control data is stored. A car operation panel provided with the in-panel communication means;
With
The elevator car apparatus according to any one of claims 1 to 5 , wherein the master board and the slave board are provided inside the car operation panel. A car operation panel provided with the in-panel communication means;
With
The car operation panel is
Inji control board to control the indicator,
An announcement control board for controlling the speaker;
A button control board for controlling the car button;
Comprising at least two control boards
The master board consists of one of the control boards provided in the car operation panel,
The elevator car apparatus according to any one of claims 1 to 5 , wherein the slave board includes the other control board provided in the car operation panel. Receiving means for receiving a radio signal output from a predetermined remote controller;
Setting means for setting the elevator based on the signal received by the receiving means;
Based on the signal received by the receiving means, a master board for storing the current setting contents of the elevator as remote control data in the first storage means,
A slave board connected to the master board by means of in-panel communication means, and based on the data received from the master board, the current setting contents of the elevator are stored as remote control data in the second storage means;
A car operation panel provided with the in-panel communication means;
With
The car operation panel is
Inji control board to control the indicator,
An announcement control board for controlling the speaker;
A button control board for controlling the car button;
Comprising at least two control boards
The master board consists of one of the control boards provided in the car operation panel,
The slave board is composed of another control board provided in the car operation panel.
Elevator car equipment.

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