JP2012046256A - Elevator device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To prevent an ID setting error caused by a human error by reducing ID setting switches provided at a hall terminal of each floor.SOLUTION: An elevator main control device 1 and the hall terminals 21-2N are connected by a communication line 3 and a power supply line 4, and power is supplied from the main control device 1 to the hall terminals 21-2N. Each of the hall terminals 21-2N includes a CPU 5, a RAM 6, a transmitting-receiving circuit part 7, a power supply input part 8 and an analog to digital conversion circuit part 9, and further includes a load resistance 10 connected to the power supply line 4, and a transistor 11 controlling the load resistance 10. Since electric currents consumed by the hall terminals 21-2N flow to the power supply line 4, difference arises to a source voltage level applied to the hall terminals 21-2N in sequence of the hall terminal 21>the hall terminal 22>the hall terminal 23>the hall terminal 2N. The difference is relatively compared to determine formal IDs of the hall terminals 21-2N.

Description

  The present invention relates to an elevator apparatus, and more particularly to an apparatus suitable for setting a unique identification number (ID) of a hall terminal device installed on each floor.

  The elevator hall is equipped with hall terminal devices consisting of hall call buttons and response lamps. For example, in an elevator for a high floor as in Patent Document 1, the number of hall terminal devices is proportional to the number of floors. And the number to install increases.

  Since hall terminal devices that increase in proportion to the number of floors in this way need to be identified for each floor to be installed, an ID setting switch is provided for each hall terminal device. The ID of the hall terminal device was determined.

JP-A-6-271217

  In the prior art, since the ID of each hall terminal device is set by setting a switch provided for each hall terminal device, there is a problem of high cost. Further, since the switch setting is manual, there is a problem that a setting error due to human error occurs.

  On the other hand, Patent Document 1 proposes a solution by increasing the number of hall terminal devices due to higher floors and causing a voltage drop of the power supply cable as a problem. However, the setting of the ID is not considered.

  An object of the present invention is to reduce the number of switches provided in the hall terminal device and prevent an ID setting error of the hall terminal device due to human error.

  In order to achieve such an object, one feature of the present invention is that a unique identification number (ID) of the hall terminal device installed for each floor is a voltage from a power source supplied to each hall terminal device. The decision is based on the difference in level.

  Other objects and features of the present invention will be clarified in the embodiments described below.

  According to the present invention, the switch provided for each hall terminal device is not required, and setting by the switch is not required, so that an ID setting error of the hall terminal device can be prevented.

It is a principal part schematic diagram which shows one Embodiment of the elevator apparatus which concerns on this invention. It is one Example of the processing flow which comprises the main-control apparatus of FIG. It is one Example of the processing flow which comprises the hall terminal device of FIG.

  Hereinafter, embodiments of the present invention will be described with reference to FIGS. Each is an embodiment of the present invention, FIG. 1 is a schematic diagram of the main part of the entire elevator apparatus, FIG. 2 is a processing flow on the main control apparatus side, and FIG. 3 is a processing flow on the hall terminal equipment side.

  In FIG. 1, the elevator main control device 1 and the hall terminal devices 21 to 2N are connected by a communication line 3 and a power supply line 4, and power is supplied from the main control device 1 to the hall terminal devices 21 to 2N. The hall terminal devices 21 to 2N include a CPU 5, a RAM 6, a transmission / reception circuit unit 7, a power input unit 8, and an AD conversion circuit unit 9. Furthermore, a load resistor 10 connected to the power supply line 4 and a transistor 11 for controlling the load resistor 10 are provided. The N is the number of hall terminal devices connected.

  In the configuration of FIG. 1, since the current consumed by the hall terminal devices 21 to 2N flows through the power supply line 4, the power supply voltage level supplied to the hall terminal devices 21 to 2N is the hall terminal device 21> the hall terminal device 22>. There is a difference between the hall terminal device 23> the hall terminal device 2N. By comparing these differences relative to each other, the formal IDs of the hall terminal devices 21 to 2N are determined.

  Next, details of the processing procedure will be described with reference to the flowcharts of FIGS.

  First, the hall terminal devices 21 to 2N are in a state of waiting for receiving a voltage level inquiry. Main controller 1 sets variable n to 0 in step S101 of FIG. Next, in step S102, broadcast transmission is performed from the main control device 1 to all hall terminal devices in order to inquire about what voltage the supplied power supply voltage level is. In step S103, the hall terminal devices 21 to 2N Is ready to receive the voltage level (temporary ID).

  On the other hand, when the CPU 5 provided in the hall terminal devices 21 to 2N receives the inquiry command via the transmission / reception circuit 7 in step S201 of FIG. 3, the load resistor 10 is turned on by the transistor 11 in step S202, and the power supply line 4 Increase the current to flow through. This procedure S202 makes a difference in the power supply voltage level supplied to the hall terminal devices 21 to 2N, so that the voltage level comparison in procedure S107 is facilitated.

  Next, in step S203, the supplied power supply voltage level is measured and AD conversion is performed, and in step S204, the measurement result is stored in the RAM 6 as a temporary ID. Next, in step S205, the CPU 5 provided in each hall terminal device transmits the temporary ID data stored in step 204 to the main controller 1 via the transmission / reception circuit 7. Next, in step S206, the load resistor 10 is turned off by the transistor 11, and the transmission data from the main controller 1 is awaited.

  When receiving the voltage level (temporary ID) from the hall terminal devices 21 to 2N in step S103 of FIG. 2, main controller 1 stores the voltage level value (temporary ID) in step S104, and variable n is set in step S105. It is determined whether or not N matches. If they do not match, 1 is added to the variable n in step S10, and a state of waiting for receiving a voltage level (temporary ID) from another hall terminal device is entered.

  Step S103 to step S106 are repeated until the variable n matches the number N of hall terminal device connections in step S105. When the variable n matches the number N of hall terminal devices connected, the voltage level (temporary ID) stored in step S107 is relatively compared. In the configuration of FIG. 1, since the data of the hall terminal device 21 is the largest, then the hall terminal device 22, then the hall terminal device 23, and the smallest is the hall terminal device 2N, the official ID of the hall terminal device 21 is obtained in step S108. 1, the formal ID of the hall terminal device 22 is 2, the formal ID of the hall terminal device 23 is 3, and the formal ID of the hall terminal device 2N is N.

  Next, in step S110, data with the formal ID added to the temporary ID is transmitted to the hall terminal device, and the system waits for reception of the formal ID setting completion signal. Upon receiving the data in step S207, the hall terminal device extracts a temporary ID in step S208, and determines in step S209 whether it matches the temporary ID stored in step S204.

  If they match, the formal ID is extracted in step S210, the temporary ID stored in the RAM in step S211 is changed to the formal ID, and the formal ID setting completion signal is transmitted to the main controller 1 in step S212. Completed. If they do not match, the state again waits for transmission data from the main control device 1.

  Then, when receiving the formal ID setting completion signal in step S110, main controller 1 determines in step S111 whether the formal ID has been transmitted to all the hall terminal devices. If not, the procedure starts from step S109. Repeat S111. When the formal ID transmission to all the hall terminal devices is completed, the setting of the main control device 1 is also completed.

  As described above, according to one embodiment of the present invention, the ID of each hall terminal device can be determined based on the difference in power supply voltage level supplied to the hall terminal device. Since the switch provided in is no longer necessary and the setting of the switch is also unnecessary, it is possible to prevent the ID setting error of the hall terminal device.

DESCRIPTION OF SYMBOLS 1 ... Elevator main-control apparatus 21-2N ... Hall terminal device 3 ... Communication line 4 ... Power supply line 5 ... CPU
6 ... RAM
7. Transmission / reception circuit unit 8. Power supply input unit 9. AD conversion circuit unit 10. Load resistor 11 ... Load resistance control transistor

Claims (4)

  A main control device that controls the operation of the elevator, a hall terminal device that performs call input and operation display of each floor hall, a communication line between the main control device and the hall terminal device, and a power supply to the hall terminal device In an elevator apparatus equipped with a common power supply line for supplying a unique identification number (ID) of the hall terminal device installed for each floor, a difference in voltage level from the power source supplied to each hall terminal device The elevator apparatus characterized by determining based on.   2. The elevator apparatus according to claim 1, wherein each of the hall terminal devices includes a CPU, converts a supplied power supply voltage level into an A / D converter, stores the converted voltage in a storage unit, and transmits the same to the main controller via the communication line. It is comprised so that it may carry out. The elevator apparatus characterized by the above-mentioned.   3. The elevator apparatus according to claim 2, wherein the main control device determines the ID of each hall terminal device by comparing the voltage level from each hall terminal device transmitted via the communication line, The elevator apparatus is configured to transmit to each of the hall terminal devices.   The elevator apparatus according to any one of claims 1 to 3, wherein the hall terminal device includes a switching element that grounds a voltage from the power source through a load resistor, and the hall terminal device has a unique identification number (ID). Is determined using a voltage level when the switching element is operated and grounded.

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