JPWO2011048664A1 - Elevator safety device - Google Patents

Abstract

Provided is an elevator safety device capable of reliably detecting a failure in each of two relay drivers provided corresponding to a relay for cutting off the power supply of a motor or a brake. For this reason, a cooperative operation is performed such that one of the first and second arithmetic devices outputs a drive command and the other of the first and second arithmetic devices outputs a shut-off command, and the first and second arithmetic devices The failure diagnosis of the first and second drivers is performed based on the output state of the contact signal for diagnosis by the contact signal output device during the cooperative operation.

Description

  The present invention relates to an elevator safety device.

  In a conventional elevator safety device, an arithmetic device controls driving of a relay via a relay driver, and controls power supply to a motor or a brake. However, the power supply to the motor and brake may not be cut off in an emergency due to an abnormality in the arithmetic unit or a short circuit failure of the driver.

  Here, two switches are connected in series to the brake coil, and when one of the switches fails, the other is used to cut off the current flowing through the brake coil (for example, Patent Document 1). reference).

International Publication No. 2008/152722

  However, the one described in Patent Document 1 cannot detect the other failure of the switch. Therefore, even if the two switches described in Patent Document 1 are applied as relay drivers, there is a problem in that any one of the relay drivers cannot detect a failure.

  The present invention has been made to solve the above-described problems, and the object of the present invention is assured for each of the two relay drivers provided corresponding to the relays for cutting off the power supply of the motor or the brake. It is another object of the present invention to provide an elevator safety device that can detect a failure.

  An elevator safety device according to the present invention includes a relay having a function of cutting off power supply to an elevator motor or brake, a first driver connected in series to the relay, the relay, and the first driver. A first driver connected in series to the first driver, and one of a drive command for applying a drive voltage to the relay and a cut-off command for cutting off the drive voltage according to the situation. A first arithmetic unit, a second arithmetic unit that outputs one of a driving command for applying the driving voltage and a blocking command for blocking the driving voltage to the second driver according to a situation, and A contact signal output device that outputs a contact signal for diagnosis according to an operation, and one of the first and second arithmetic devices outputs the drive command and the first and second A cooperative operation is performed so that the other of the arithmetic devices outputs the cutoff command, and the first and second arithmetic devices are based on an output state of the diagnostic contact signal by the contact signal output device during the cooperative operation. Thus, failure diagnosis of the first and second drivers is performed.

  According to the present invention, a failure can be reliably detected for each of the two relay drivers provided corresponding to the relays for cutting off the power supply of the motor or the brake.

BRIEF DESCRIPTION OF THE DRAWINGS It is a block diagram of the whole elevator in which the elevator safety device in Embodiment 1 of this invention is utilized. It is a figure for demonstrating the failure diagnosis procedure when the contact for motor power relay diagnosis of the safety device of the elevator in Embodiment 1 of this invention is closing. It is a figure for demonstrating the failure diagnosis procedure when the contact for motor power relay diagnosis of the safety device of the elevator in Embodiment 1 of this invention is open | released.

  A mode for carrying out the invention will be described with reference to the accompanying drawings. In addition, in each figure, the same code | symbol is attached | subjected to the part which is the same or it corresponds, The duplication description is simplified or abbreviate | omitted suitably.

Embodiment 1 FIG.
1 is a configuration diagram of an entire elevator in which an elevator safety device according to Embodiment 1 of the present invention is used.
In FIG. 1, reference numeral 1 denotes a motor power source. 2 is a power converter. 3 is a motor. The motor 3 has a function of rotating by electric power supplied from the motor power source 1 via the power conversion device 2. 4 is a sheave. The sheave 4 has a function of rotating following the rotation of the motor 3.

  5 is a main rope. The main rope 5 is wound around the sheave 4. 6 is a car. The car 6 is connected to one end of the main rope 5. 7 is a counterweight. This counterweight 7 is connected to the other end of the main rope 5. Reference numeral 8 denotes a brake power source. 9 is a brake. The brake 9 has a function of braking the rotation of the motor 3 when the electric power supplied from the brake power supply 8 is cut off.

  Reference numeral 10 denotes a motor power relay contact. The motor power relay contact 10 is composed of a contact. The motor power relay contact 10 is provided on the wiring between the motor power 1 and the power converter 2. Reference numeral 11 denotes a brake power relay contact. The brake power contact 11 is composed of a contact. The brake power supply relay contact 11 is provided on the wiring between the brake power supply 8 and the brake 9.

  Reference numeral 12 denotes an electronic safety device. The electronic safety device 12 has a function of controlling closing and opening of the motor power relay contact 10 and the brake power relay contact 11. The electronic safety device 12 has a function of detecting an emergency situation of the elevator.

  In the elevator configured as described above, when an emergency occurs, the motor power relay contact 10 and the brake power relay contact 11 are opened under the control of the electronic safety device 12. When the relay contacts 10 and 11 are opened, power supply to the motor 3 and the brake 9 is cut off. Then, the brake 9 brakes the motor 3 that has lost its driving force, so that the car 6 is brought to an emergency stop. By this emergency stop, users in the car 6 can be secured.

Next, the internal configuration of the electronic safety device 12 will be described in more detail.
Reference numeral 13 denotes a motor power relay. The motor power relay 13 is disposed on a motor power relay wiring 14 provided between the power source and the ground. The motor power relay 13 is for controlling closing and opening of the motor power relay contact 10. That is, when a drive voltage is applied to the motor power relay 13, the motor power relay contact 10 is closed. On the other hand, when the drive voltage to the motor power relay 13 is cut off, the motor power relay contact 10 is opened.

  Reference numeral 15 denotes a first motor power relay driver. The first motor power relay driver 15 is composed of a transistor. The first motor power relay driver 15 is connected in series to the motor power relay 13 on the motor power relay wiring 14. Reference numeral 16 denotes a second motor power relay driver. The second motor power relay driver 16 is formed of a transistor. The second motor power relay driver 16 is connected in series to the motor power relay 13 and the first motor power relay driver 15 on the motor power relay wiring 14. That is, the first and second motor power relay drivers 15 and 16 have a dual system configuration with respect to the motor power relay 13.

  Reference numeral 17 denotes a brake power relay. The brake power relay 17 is disposed on a brake power relay wiring 18 provided between the power source and the ground. The brake power relay 17 is for controlling closing and opening of the brake power relay contact 11. That is, when a drive voltage is applied to the brake power relay 17, the brake power relay contact 11 is closed. On the other hand, when the drive voltage to the brake power relay 17 is cut off, the brake power relay contact 11 is opened.

  Reference numeral 19 denotes a first brake power relay driver. The first brake power relay driver 19 is composed of a transistor. The first brake power relay driver 19 is connected in series to the brake power relay 17 on the brake power relay wiring 18. Reference numeral 20 denotes a second brake power relay driver. The second brake power relay driver 20 is formed of a transistor. The second brake power relay driver 20 is connected in series to the brake power relay 17 and the first brake power relay driver 19 on the brake power relay wiring 18. That is, the first and second brake power relay drivers 20 have a dual system configuration with respect to the brake power relay 17.

  The controls of the drivers 15, 16, 19, and 20 also have a dual system configuration using the first arithmetic device 21 and the second arithmetic device 2. Specifically, the first arithmetic unit 21 has a function of outputting a control command corresponding to the situation to the first motor power relay driver 15 and the first brake power relay driver 19. The second arithmetic unit 22 has a function of outputting a control command corresponding to the situation to the second motor power relay driver 16 and the second brake power relay driver 20.

  More specifically, the first arithmetic unit 21 has a function of outputting a drive command for applying a drive voltage to the motor power relay 13 to the first motor power relay driver 15. Further, the first arithmetic unit 21 has a function of outputting a cutoff command for cutting off the drive voltage to the motor power relay 13 to the first motor power relay driver 15. Further, the first arithmetic unit 21 has a function of outputting a drive command for applying a drive voltage to the brake power supply relay 17 to the first brake power supply relay driver 19. In addition, the first arithmetic unit 21 has a function of outputting a cut-off command for cutting off the drive voltage to the brake power supply relay 17 to the first brake power supply relay driver 19.

  On the other hand, the second arithmetic unit 22 has a function of outputting a drive command for applying a drive voltage to the motor power relay 13 to the second motor power relay driver 16. Further, the second arithmetic unit 22 has a function of outputting a cutoff command for cutting off the drive voltage to the motor power relay 13 to the second motor power relay driver 16. Further, the second arithmetic unit 22 has a function of outputting a drive command for applying a drive voltage to the brake power supply relay 17 to the second brake power supply relay driver 20. In addition, the second arithmetic unit 22 has a function of outputting a cutoff command for cutting off the drive voltage to the brake power relay 17 to the second brake power relay driver 16.

  Reference numeral 23 denotes a motor power relay diagnosis contact. The motor power relay diagnosis contact 23 is composed of a contact. The motor power relay diagnosis contact 23 is provided on the wiring between the power source and the first and second arithmetic devices 21 and 22. This motor power relay diagnosis contact 23 functions as a contact signal output device that outputs a diagnosis a contact signal according to the operation of the motor power relay 13.

  Reference numeral 24 denotes a brake power relay diagnostic contact. The brake power relay diagnosis contact 24 is composed of a contact. The brake power relay diagnosis contact 24 is provided on the wiring between the power source and the first and second arithmetic devices 21 and 22. The brake power relay diagnosis contact 24 functions as a contact signal output device that outputs a diagnosis a contact signal in accordance with the operation of the brake power relay 17.

  Various signals indicating the operation state of the elevator such as the stop state of the car 6 are input to the electronic safety device 12 having the above configuration. If the car 6 stops during normal operation of the elevator, the first and second arithmetic devices 21 and 22 perform a cooperative operation to self-diagnose the failure of each relay driver 15, 16, 19, and 20. Is configured to do.

  Specifically, one of the first and second arithmetic devices 21 and 22 outputs a drive command to the corresponding driver. At the same time, the other of the first and second arithmetic devices 21 and 22 outputs a cutoff command to the corresponding driver. Then, the first and second arithmetic units 21 and 22 monitor the output state of the diagnostic contact signals via the diagnostic contacts 23 and 24 and perform fault diagnosis of the relay drivers 15, 16, 19, and 20. Configured to do.

  Next, a failure diagnosis method for the first and second motor power relay drivers 15 and 16 and the first and second brake power relay drivers 19 and 20 will be described in detail. The failure diagnosis of the first and second motor power relay drivers 15 and 16 and the failure diagnosis of the first and second brake power relay drivers 19 and 20 are performed in the same manner. Therefore, hereinafter, failure diagnosis of the first and second motor power supply relay drivers 15 and 16 will be described with reference to FIGS. 2 and 3.

  FIG. 2 is a diagram for explaining a failure diagnosis procedure when the motor power relay diagnosis contact of the elevator safety device according to Embodiment 1 of the present invention is closed. FIG. 3 is a diagram for explaining a failure diagnosis procedure when the motor power relay diagnosis contact of the elevator safety device according to Embodiment 1 of the present invention is open.

  First, the case where the motor power supply relay diagnosis contact 23 is closed will be described with reference to FIG. In FIG. 2, reference numeral 25 denotes a control command to the first motor power relay driver 15. Specifically, the first arithmetic unit 21 outputs a Hi level signal as a drive command to the control terminal of the first motor power relay driver 15. On the other hand, the first arithmetic unit 21 outputs a Low level signal as a cutoff command to the control terminal of the first motor power relay driver 15.

  Reference numeral 26 denotes a control command to the second motor power supply relay driver 16. Specifically, the second arithmetic unit 22 outputs a Hi level signal as a drive command to the control terminal of the second motor power relay driver 16. On the other hand, the second arithmetic unit 22 outputs a Low level signal as a cutoff command to the control terminal of the second motor power relay driver 16.

  Reference numeral 27 denotes a signal state of the motor power relay diagnosis contact 23. Specifically, when the motor power relay diagnosis contact 23 is closed, a Hi level signal is input to the first and second arithmetic devices 21 and 22. On the other hand, when the motor power relay diagnostic contact 23 is open, a low level signal is input to the first and second arithmetic devices 21 and 22.

  In the initial state of FIG. 2, the first and second arithmetic devices 21 and 22 both output drive commands as control commands 25 and 26. At this time, if both the first and second motor power relay drivers 15 and 16 are in the ON state, a drive voltage is applied to the motor power relay 13. In this case, the signal state 27 of the motor power supply relay diagnosis contact 23 is closed.

  In this state, first, the first arithmetic unit 21 outputs a cutoff command as the control command 25, and the second arithmetic unit 22 maintains the output of the drive command as the control command 26. At this time, the signal state 27 of the motor power supply relay diagnosis contact 23 is in an open state before the predetermined time elapses after the first arithmetic unit 21 outputs the cutoff command. In this case, the first and second arithmetic devices 21 and 22 determine that the first motor power driver 15 has been turned off following the cutoff command, and determine that no short circuit abnormality has occurred.

  Thereafter, the first arithmetic unit 21 outputs a drive command as the control command 25 and the second arithmetic unit 22 outputs a shut-off command as the control command 26. However, the signal state 27 of the motor power supply relay diagnosis contact 23 remains open even if a predetermined time has elapsed after the second arithmetic unit 22 outputs the cutoff command. In this case, the first and second arithmetic devices 21 and 22 determine that the second motor power driver 16 maintains the ON state without following the cutoff command, and determines that a short circuit abnormality has occurred. .

  Next, the case where the motor power relay diagnosis contact 23 is open will be described with reference to FIG. In the initial state of FIG. 3, the first and second arithmetic devices 21 and 22 both output a cutoff command as the control commands 25 and 26. At this time, if at least one of the first and second motor power relay drivers 15 and 16 is in the OFF state, the drive voltage to the motor power relay 13 is cut off. In this case, the signal state 27 of the motor power relay diagnosis contact 23 is in an open state.

  In this state, first, the first arithmetic unit 21 maintains the output of the shut-off command as the control command 25, and the second arithmetic unit 22 outputs the drive command as the control command 26. At this time, after the second arithmetic unit 22 outputs the drive command, the signal state 27 of the motor power supply relay diagnosis contact 23 remains open even if a predetermined time has elapsed. In this case, the first and second arithmetic devices 21 and 22 determine that the first motor power driver 15 is maintaining the OFF state following the cutoff command, and determines that no short circuit abnormality has occurred.

  Thereafter, the first arithmetic unit 21 outputs a drive command as the control command 25 and the second arithmetic unit 22 outputs a shut-off command as the control command 26. However, after the first arithmetic unit 21 outputs the drive command, the signal state 27 of the motor power supply relay diagnosis contact 23 becomes an open state within a predetermined time set in advance. In this case, the first and second arithmetic devices 21 and 22 determine that the second motor power driver 16 maintains the ON state without following the cutoff command, and determines that a short circuit abnormality has occurred. .

  According to the first embodiment described above, one of the first and second arithmetic devices 21 and 22 outputs a drive command, and the other of the first and second arithmetic devices 21 and 22 outputs a cutoff command. A cooperative operation is performed. And the 1st and 2nd arithmetic units 21 and 22 perform failure diagnosis of each driver 15 etc. based on the signal state of each diagnostic contact 23 and 24 in cooperation operation.

  Specifically, when the a-contact signal is input to the first and second arithmetic units 21 and 22, after the cooperative operation is performed, the a-contact signal When the input continues, it is determined that the driver corresponding to the other of the first and second arithmetic devices 21 and 22 is abnormal. Further, when the a contact signal is input before the predetermined time elapses after the cooperative operation is performed when the a contact command is not input, the first and second arithmetic units 21. , 22 is determined to be abnormal.

  Thereby, a failure can be reliably detected for each of the relay drivers 15 and the like. For this reason, even if the relay driver or the arithmetic unit on one side of the system breaks down in an emergency, the power supply to the motor 1 and the brake 9 can be reliably cut off.

  Further, the first and second arithmetic devices 21 and 22 perform failure diagnosis of each relay driver 15 and the like when the car 6 is stopped. For this reason, failure diagnosis of each relay driver 15 etc. can be performed, without disturbing operation of an elevator.

  As described above, the elevator safety device according to the present invention can be used for an elevator that cuts off power supply to a motor or a brake in an emergency.

1 motor power, 2 power converter, 3 motor, 4 sheave,
5 main rope, 6 passenger car, 7 counterweight, 8 brake power,
9 Brake, 10 Motor power relay contact, 11 Brake power relay contact,
12 electronic safety device, 13 motor power relay, 14 motor power relay wiring, 15 first motor power relay driver, 16 second motor power relay driver,
17 Brake power relay, 18 Brake power relay wiring,
19 First brake power relay driver, 20 Second brake power relay driver, 21 First arithmetic device, 22 Second arithmetic device, 23 Motor power relay diagnostic contact,
24 Brake power relay diagnostic contact, 25 Control command to the first driver,
26 Control command to the second driver, 27 Motor power relay diagnostic contact signal

Claims (4)

A relay having a function of cutting off power supply to the elevator motor or brake;
A first driver connected in series to the relay;
A second driver connected in series with the relay and the first driver;
A first arithmetic unit that outputs one of a drive command for applying a drive voltage to the relay and a cut-off command for cutting off the drive voltage to the first driver according to a situation;
A second arithmetic unit that outputs one of a drive command for applying the drive voltage and a cut-off command for cutting off the drive voltage to the second driver according to a situation;
A contact signal output device that outputs a contact signal for diagnosis according to the operation of the relay;
With
A cooperative operation is performed such that one of the first and second arithmetic devices outputs the drive command and the other of the first and second arithmetic devices outputs the shut-off command,
The first and second arithmetic devices perform failure diagnosis of the first and second drivers based on an output state of the diagnostic contact signal by the contact signal output device during the cooperative operation. Elevator safety device. The contact signal output device outputs a contact signal as the diagnostic contact signal,
The first and second arithmetic units may perform a predetermined time after the cooperative operation is performed when the contact signal a is input to the first and second arithmetic units. 2. The elevator safety device according to claim 1, wherein when the input of the a contact signal is continued, the driver corresponding to the other of the first and second arithmetic units is determined to be abnormal.   The first and second arithmetic units may perform a predetermined time after the cooperative operation is performed when the a contact command is not input to the first and second arithmetic units. The elevator safety device according to claim 2, wherein when the a contact signal is input, a driver corresponding to the other of the first and second arithmetic units is determined to be abnormal.   The said 1st and 2nd arithmetic unit performs the said cooperation operation | movement at the time of the stop of the said elevator car, and performs the failure diagnosis of the said 1st and 2nd driver, The Claims 1-3 characterized by the above-mentioned. The elevator safety device according to any one of the above.

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