JP4854882B2 - Elevator control device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an elevator control device that performs a plurality of car allocation processes in response to hall information, and in particular, can sufficiently reduce power consumption during a standby mode and can automatically return to a normal mode when a hall button is operated. The present invention relates to an elevator control device.
[0002]
[Prior art]
A conventional elevator control device is disclosed in, for example, Japanese Patent Application Laid-Open No. 4-55272. In this case, a hall device having a microcomputer is installed for each floor, and a hall button on each floor is connected to each hall device. It is connected to the microcomputer inside.
[0003]
In the above-mentioned conventional device, serial transmission is performed between the hall device and the central control panel, hall button information for each floor is transmitted to the control panel, and button response lights and indicator information are transmitted to each floor. It is displayed on the installed hall device.
[0004]
At this time, since the landing devices on each floor need not only microcomputers but also communication ICs, a DC power source for operating these electronic circuits is required.
[0005]
FIG. 3 is a block diagram schematically showing a conventional elevator control apparatus.
In FIG. 3, 1 is a landing button installed in the elevator hall of each floor, 2 is a hall device installed for each floor and interlocked with the hall button 1, and 3 is a DC power source for supplying power to the hall device 2.
[0006]
Reference numeral 4 denotes an elevator control panel connected to all landing devices 2, which drives each landing device 2 and manages a plurality of cars (not shown) according to information from the landing device 2.
[0007]
Reference numeral 5 denotes a landing power line drawn from the elevator control panel 4, which connects the elevator control panel 4 and the DC power source 3 of each landing device 2.
Reference numeral 6 denotes a serial transmission path (hereinafter simply referred to as “transmission path”) drawn from the elevator control panel 4, and connects the elevator control panel 4 and each landing device 2.
[0008]
In the hall device 2, 21 is a microcomputer that is the main body of the hall device 2, 22 is a transceiver that communicates information with the microcomputer 21 via the hall power line 5, and 23 is interposed between the hall button 1 and the microcomputer 21. It is a button processing circuit.
[0009]
In the conventional apparatus shown in FIG. 3, information on the hall button 1 is transmitted to the microcomputer 21 via the button processing circuit 23, and further transmitted to the elevator control panel 4 via the transceiver 22 and the hall power line 5.
[0010]
For this reason, it is always necessary to supply power to the hall device 2 via the DC power source 3, and the power to the hall device 2 should be shut off even when the elevator user is absent and the vehicle does not operate for a long time. Cannot be used, and wasteful power is consumed.
[0011]
[Problems to be solved by the invention]
As described above, the conventional elevator control apparatus has a problem in that useless power consumption during standby cannot be reduced because the power backup means is not provided in the hall device 2.
[0012]
The present invention has been made to solve the above-described problems, and is an elevator that can reduce wasteful power consumption during standby and can easily return to a normal operation mode in response to an operation of a landing button. The object is to obtain a control device.
[0013]
[Means for Solving the Problems]
The elevator control device according to the present invention includes a landing button installed for each floor, a landing device including a microcomputer that is installed for each floor and receives a contact signal of the landing button, and various types of devices. Elevator control panel including a CPU that controls the supply of hall power to the hall device and a transmission path that performs various types of information communication between the hall device and the elevator control board Circuit breaker for turning on / off the hall power under the control of the CPU, a backup power source for supplying a backup voltage when the hall power is shut off, a backup voltage to the elevator control panel when the hall button is turned on, and a hall button Button backup circuit that prevents consumption of backup power when the power is off, and button processing that inputs a contact signal to the microcomputer when the landing power is supplied And a circuit, CPU has a normal mode and a standby mode as the operation mode, is ON the breaker in the normal mode, but OFF causes the circuit breaker in the standby mode.
[0014]
Further, the transmission path of the elevator control device according to the present invention also serves as a backup voltage supply path to the elevator control panel.
[0016]
Further, the CPU of the elevator control device according to the present invention shifts from the normal mode to the standby mode when the contact signal is not input from the landing device for a certain time or more, and the backup voltage in response to the contact signal in the standby mode state. Is input from the standby mode to the normal mode.
[0017]
DETAILED DESCRIPTION OF THE INVENTION
Embodiment 1 FIG.
Hereinafter, the first embodiment of the present invention will be described in detail with reference to the drawings.
FIG. 1 is a block diagram showing a first embodiment of the present invention.
In FIG. 1, the same components as those described above (see FIG. 3) are given the same reference numerals, or “A” is added after the reference numerals, and detailed description thereof is omitted.
[0018]
In the landing button 1, 1a is an up button and 1b is a down button.
In the landing device 2A, 24 is a button backup circuit that operates in response to the operation of the landing button 1, 25 is a backup power source for enabling the operation of the landing button 1 even when the DC power source 3 is shut off, and 26 is a DC power source. 3 is a DC-DC converter that variably sets the supply voltage from 3.
[0019]
That is, the hall device 2A includes a button backup circuit 24, a backup power source 25, and a DC-DC converter 26 in addition to the microcomputer 21, the transceiver 22, and the button processing circuit 23 described above.
[0020]
The button processing circuit 23 in the hall device 2A inputs a contact signal based on ON / OFF of the hall button 1 to the microcomputer 21 when the hall power is supplied from the elevator control panel 4A (in the normal mode).
[0021]
In the button processing circuit 23, PD1 and PD2 are parallel photodiodes inserted between the output terminals of the buttons 1a and 1b and the ground, respectively. PTr1 and PTr2 are phototransistors arranged opposite to the photodiodes PD1 and PD2. It is.
[0022]
The transistors PTr1 and PTr2 are turned on via the photodiodes PD1 and PD2 when the hall button 1 is operated.
Emitter (output terminal) voltages of the transistors PTr1 and PTr2 are input to the microcomputer 21.
[0023]
In the button backup circuit 24, D1 and D2 are parallel diodes, and the output terminals of the buttons 1a and 1b are individually connected to the anodes.
The output voltage B of the backup power source 25 is applied to the input terminals of the buttons 1a and 1b.
[0024]
D3 is a diode that allows the supply voltage from the DC power supply 3 to pass through, Tr is a transistor that is turned ON when the hall button 1 is operated, and R is a resistor having one end connected to the output terminal of the transceiver 22.
[0025]
The cathodes of the diodes D1 and D2 are connected to the base of the transistor Tr, the output voltage B of the backup power supply 25 is applied to the collector, and the other end of the resistor R and the cathode of the diode D3 are connected to the emitter. Has been.
[0026]
In the backup power supply 25, D4 is a diode that passes the supply voltage from the DC power supply 3, and the supply voltage from the DC power supply 3 is applied to the anode.
C is a capacitor constituting the main body of the backup power supply 25, and one end is grounded and the other end is connected to the cathode of the diode D4 to generate the output voltage B.
[0027]
The button backup circuit 24 is configured to supply the backup voltage B to the elevator control panel 4A when the landing button 1 is turned on and to prevent the backup power supply 25 from being consumed when the landing button 1 is turned off.
[0028]
The transmission path 6 includes a transmission path 61 from the landing device 2A to the elevator control panel 4A and a reception path 62 from the elevator control panel 4A to the landing apparatus 2A. The transmission path 61 and the reception path 62 are connected to the transceiver 22. It is connected.
The transmission line 6 also serves as a supply path for the backup voltage B to the elevator control panel 4A.
[0029]
In the elevator control panel 4A, 40 is a main circuit connected to the power supply line, 41 is a CPU constituting the main body function of the elevator control panel 4A, 42 is a transceiver that performs information communication with the hall device 2A via the transmission path 6, A circuit breaker 43 is inserted into the landing power supply line 5 and is turned ON / OFF by the CPU 41, and a button backup input circuit 44 is connected to the button backup circuit 24 via the transmission path 61.
[0030]
As shown in FIG. 1, a circuit breaker 43 for shutting off the landing power source 2A during the standby mode is added to the elevator control panel 4A, and a backup power source 25 for shutting off the landing power source 2A is placed in the landing device 2A. to add.
[0031]
The output terminal of the hall button 1 is not only connected to the microcomputer 21 via the button processing circuit 23 but also directly connected to the transmission path 61 of the transmission path 6 via the button backup circuit 24.
[0032]
As described above, the button backup circuit 24 and the backup power source 25 are provided in the hall device 2A, and the circuit breaker 43 and the button backup input circuit 44 are provided in the elevator control panel 4A. An automatic return function during operation is effectively realized.
[0033]
That is, during normal operation while the elevator is moving up and down, the button information of the hall button 1 is converted into a serial signal by the microcomputer 21 in the hall device 2A and transmitted to the elevator control panel 4A via the transmission path 6.
[0034]
On the other hand, when there is no ON information (contact signal) of the landing button 1 and the elevator does not operate for a certain period of time (standby mode), the power supply to the landing device 2A is cut off.
At this time, the microcomputer 21 in the hall device 2A does not operate, but the operation information (contact signal) of the hall button 1 is transmitted to the elevator control panel 4A via the transmission path 6 by the output voltage of the backup power source 25.
[0035]
In response to this, the CPU 41 in the elevator control panel 4A in the standby mode resumes power supply to the landing device 2A, and the microcomputer 21 in the landing device 2A again uses the button information as a serial signal as the elevator control panel 4A. To communicate.
[0036]
Here, only one landing device 2A is representatively shown, but a landing device (not shown) having the same configuration is installed for each floor, and the landing power supply line 5 and the transmission line 6 are respectively connected. To the elevator control panel 4A.
[0037]
Next, a specific operation according to the first embodiment of the present invention shown in FIG. 1 will be described with reference to the timing chart of FIG.
FIG. 2 shows the state change of each part and the communication state of the transmission path 61 during normal operation and standby mode.
[0038]
In FIG. 2, the voltages of the DC power supply 3 and the backup power supply 25 change in response to the ON / OFF operation of the circuit breaker 43 in the elevator control panel 4A.
Further, the ON / OFF state of the button processing circuit 23, the output voltage of the button backup circuit 24, the operating state of the microcomputer 21, the input voltage of the button backup input circuit 44, and the operating state of the CPU 41 respond to ON / OFF of the hall button 1. And change.
[0039]
During normal operation, the circuit breaker 43 in the elevator control panel 4A is turned on under the control of the CPU 41, and the AC power is supplied to the DC power supply 3 via the landing power supply line 5. , DC power is supplied to the hall device 2A.
[0040]
Therefore, in the backup power supply 25 in the hall device 2A, the capacitor C is charged through the diode D4.
At this time, when the elevator user presses the hall button 1, button information is taken into the microcomputer 21 via the button processing circuit 23.
[0041]
The microcomputer 21 converts the button information into a serial signal and transmits it from the transceiver 22 to the CPU 41 in the elevator control panel 4A via the transmission path 61 of the transmission path 6 and the transceiver 42.
[0042]
In such a normal operation state, for example, when the landing button 1 is not operated at all (no call is generated) and the elevator does not operate for a certain time (standby mode), the CPU 41 in the elevator control panel 4A It shifts to the standby mode and turns off the circuit breaker 43.
[0043]
As a result, the power supply to the landing power line 5 is cut off, so the DC power supply 3 stops the power supply to the landing device 2A, and at the same time, the microcomputer 21 and the transceiver 22 in the landing device 2A stop operating. To do.
[0044]
Accordingly, the power consumption to the landing device 2A is almost zero.
Further, the supply of the pull-up power from the DC power supply 3 is also stopped, so that the transmission path 61 of the transmission path 6 becomes the “LOW” level.
[0045]
At this time, since the electric power stored in the capacitor C in the backup power supply 25 is not consumed unless the landing button 1 is pressed (the transistor Tr is not turned on), the output voltage level during the operation of the landing button 1 is kept.
[0046]
When the user presses the landing button 1 during such a standby mode, the backup voltage B from the capacitor C is applied to the base of the transistor Tr in the button backup circuit 24.
[0047]
As a result, the transistor Tr is turned on, the voltage of the capacitor C in the backup power supply 25 is supplied to the transmission line 6 via the button backup circuit 24, and the transmission line 61 of the transmission line 6 becomes the “HIGH” level.
[0048]
The “HIGH” level signal based on the operation of the landing button 1 is input to the button backup input circuit 44 in the elevator control panel 4A via the transmission path 61 and transmitted to the CPU 41.
[0049]
In response to this, the CPU 41 cancels the standby mode, turns on the circuit breaker 43, and supplies power to the hall device 2A via the DC power source 3.
Accordingly, the microcomputer 21 in the hall device 2A resumes its operation, and button information is transmitted as a serial signal from the microcomputer 21 to the CPU 41 in the elevator control panel 4A as in the normal operation described above.
[0050]
In FIG. 1, the capacitor C is used as the backup power source 25, but a battery may be used.
Further, in order to input the button information to the elevator control panel 2 as a contact signal, the serial signal transmission path 6 is used together, but a dedicated line may be provided.
[0051]
Furthermore, although the button processing circuit 23, the button backup circuit 24, and the backup power source 25 are provided in the hall device 2A, they may be configured as external circuits.
Similarly, the circuit breaker 43 and the button backup input circuit 44 are provided in the elevator control panel 4A, but may be configured as an external circuit.
[0052]
By configuring as described above, when the elevator is in the standby mode, the power supply to the landing device 2A is cut off, and the microcomputer 21 in the landing device 2A is completely stopped. it can.
[0053]
Further, due to the action of the button backup circuit 24, the backup power source 25 does not consume power as long as the landing button 1 is not turned on (does not push), and therefore, backup for a long time is possible.
[0054]
Further, by pressing the landing button 1, it is possible to automatically return to the normal operation mode. Therefore, it is possible to prompt the power supply to be restored from all floors having the landing button 1.
Thereby, in the standby mode, the elevator can be returned to the operating state from each floor where the hall button 1 is located.
[0055]
【The invention's effect】
As described above, according to the present invention, a landing button provided for each floor, a landing device including a microcomputer that is installed for each floor and receives a contact signal of the landing button, and the landing device And an elevator control panel including a CPU for controlling the supply of landing power to the landing device, and an elevator including a transmission path for performing various information communication between the landing device and the elevator control panel. In the control device, a circuit breaker that turns on / off the hall power under the control of the CPU, a backup power source that supplies a backup voltage when the hall power is shut off, and a backup voltage that is supplied to the elevator control panel when the hall button is turned on, A button backup circuit that prevents consumption of backup power when the landing button is OFF, and a button processing circuit that inputs a contact signal to the microcomputer when the landing power is supplied With the door, CPU has a normal mode and a standby mode as the operation mode, is ON the breaker in the normal mode, since OFF causes the circuit breaker in the standby mode, the saving unnecessary power consumption in the standby There is an effect that an elevator control device that can easily return to the normal operation mode in response to the operation of the landing button can be obtained.
Further, according to the present invention, the CPU has a normal mode and a standby mode as operation modes, and the circuit breaker is turned on in the normal mode and the circuit breaker is turned off in the standby mode. As a result, it is possible to obtain an elevator control device that can reduce power consumption and can easily return to a normal operation mode in response to an operation of a landing button.
[0056]
Further, according to the present invention, since the transmission line also serves as a backup voltage supply path to the elevator control panel, an elevator control device having a simplified circuit configuration can be obtained.
[0058]
Further, according to the present invention, the CPU shifts from the normal mode to the standby mode when the contact signal is not input from the landing device for a predetermined time or more, and the backup voltage responding to the contact signal is input in the standby mode state. In this case, since the standby mode is returned to the normal mode, it is possible to save unnecessary power consumption during standby and to easily return to the normal operation mode in response to the operation of the landing button. There is an effect that a device is obtained.
[Brief description of the drawings]
FIG. 1 is a block configuration diagram showing a first embodiment of the present invention.
FIG. 2 is a timing chart showing an operation according to the first embodiment of the present invention.
FIG. 3 is a block diagram showing a conventional elevator control device.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 landing button, 2A landing apparatus, 21 microcomputer, 23 button processing circuit, 24 button backup circuit, 25 backup power supply, 4A elevator control panel, 41 CPU, 43 circuit breaker, 44 button backup input circuit, 6 transmission path

Claims (3)

A hall button installed on each floor,
A hall device including a microcomputer that is installed for each floor and receives a contact signal of the hall button;
An elevator control panel including a CPU that performs various types of information communication with the hall device and controls supply of hall power to the hall device;
In an elevator control device comprising: a transmission path for performing various types of information communication between the hall device and the elevator control panel;
A circuit breaker for turning on / off the hall power source under the control of the CPU;
A backup power supply for supplying a backup voltage when the hall power supply is shut off;
A button backup circuit for supplying the backup voltage to the elevator control panel when the landing button is ON, and preventing consumption of the backup power source when the landing button is OFF;
A button processing circuit for inputting the contact signal to the microcomputer when the hall power is supplied ,
The CPU has a normal mode and a standby mode as operation modes, and the circuit breaker is turned on in the normal mode, and the circuit breaker is turned off in the standby mode .   The elevator control device according to claim 1, wherein the transmission path also serves as a supply path of the backup voltage to the elevator control panel. The CPU
When the contact signal is not input from the hall device for a certain time or more, the normal mode is shifted to the standby mode,
3. The elevator control according to claim 1 , wherein when the backup voltage in response to the contact signal is input in the standby mode state, the normal mode is restored from the standby mode. 4. apparatus.

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