JP7297138B1 - Elevator hall power supply device and power supply method - Google Patents

Abstract

The present invention provides an elevator hall power supply device capable of suppressing wasteful power consumption even when operating in a state where operation display equipment consumes less current.
An elevator hall power supply device (1) includes a first power supply section (31) that supplies DC power to a first operation display device (20) and a second power supply that can supply DC power to a second operation display device (40). section 51, selection switches 53 and 55 for selecting a supply source of DC power from either the first power supply section 31 or the second power supply section 51 to the second operation display device 40, and a first current consumption Based on the current consumption value of the first operation display device 20 estimated by the estimation unit 26 and the current consumption value of the second operation display device 40 estimated by the second current consumption estimation unit 46, the first power supply unit 31 and the second power supply unit 51, and a power supply determination unit 47 that controls selection switches 53 and 55 to select either one of the power supply unit 51 and the second power supply unit 51. FIG.
[Selection drawing] Fig. 1

Description

The present disclosure relates to an elevator hall power supply device and power supply method.

A conventional general elevator hall power supply device supplies DC power from an AC-DC power supply installed on each floor to an operation display device having indicators, push buttons, etc. installed in the elevator hall of each floor. It's working. Power is supplied to the AC-DC power supply from the elevator control panel, and power is supplied from the AC-DC power supply to the operation display device when the elevator is started. The operating state of the operation display device changes according to the operation of the elevator, and the current consumption also fluctuates. Since the AC-DC power supply uses a power supply with a rated capacity that can supply the maximum current consumption of the operation display device, the operation display device often operates in a state where there is sufficient margin for current consumption in terms of the rated capacity. In this case, power is wasted due to the power factor of the AC-DC power supply.
Patent Literature 1 discloses a technique for saving energy by opening a switch provided in an AC power supply line when an elevator enters a standby mode to cut off the power supply for the hall other than the power supply for the hall on the top floor.

JP 2011-148606 A

However, the conventional elevator hall power supply device described in Patent Document 1 can be expected to save energy only in the standby mode. For this reason, there is a problem that power is wasted as described above in normal operations other than the standby mode.

The present disclosure has been made to solve the problems described above, and aims to provide an elevator hall power supply device and a power supply method that are excellent in energy saving performance.

An elevator hall power supply device according to the present disclosure supplies power to operation display devices respectively installed in a plurality of halls. An elevator hall power supply device includes a first power supply section for supplying DC power to a first operation display device installed in a first hall among a plurality of halls, and a first power supply unit installed in a second hall among the plurality of halls. a second power supply unit capable of supplying DC power to the second operation display device; a first current consumption estimation unit for estimating a current consumption value of the first operation display device; and a second current consumption estimator for estimating a current consumption value.
Further, the elevator hall power supply device includes a selection switch for selecting a supply source of DC power from either the first power supply section or the second power supply section to the second operation display device, and a first consumption current estimation section. A first power supply unit and a second power supply unit based on the current consumption value of the first operation display device estimated by and the current consumption value of the second operation display device estimated by the second current consumption estimation unit and a switch control unit that controls the selection switch to select one of

Further, the power supply method according to the present disclosure includes a first power supply unit that supplies DC power to a first operation display device installed in a first hall, and a second operation display installed in a second hall. A power supply method in an elevator hall power supply device having a second power supply unit capable of supplying DC power to a display device, wherein the current consumption value of the first operation display device and the consumption of the second operation display device either the first power supply unit or the second power supply unit based on the estimated current consumption value of the first operation display device and the estimated current consumption value of the second operation display device to select the DC power supply source for the second operation display device.

The elevator hall power supply device and power supply method according to the present disclosure have the effect of being excellent in energy saving performance.

1 is a block diagram showing the overall configuration of an elevator hall power supply device according to Embodiment 1; FIG. It is a figure which shows the power factor of a switching power supply, and the relationship of a consumption current. 4 is a flow chart showing the operation of the elevator hall power supply device according to Embodiment 1; 4 is a flow chart showing the operation of the elevator hall power supply device according to Embodiment 1; 4 is a flow chart showing the operation of the elevator hall power supply device according to Embodiment 1; 1 is a block diagram showing the overall configuration of an elevator hall power supply device according to Embodiment 1; FIG. 1 is a block diagram showing the overall configuration of an elevator hall power supply device according to Embodiment 1; FIG. 1 is a block diagram showing the overall configuration of an elevator hall power supply device according to Embodiment 1; FIG.

Hereinafter, an elevator hall power supply device and a power supply method according to embodiments of the present disclosure will be described in detail based on the drawings. In addition, the same code|symbol is attached|subjected to the part which is the same or corresponds in each figure. Redundant description of the relevant part will be simplified or omitted as appropriate.
Embodiment 1.

*** Configuration description ***
FIG. 1 is a block diagram showing the overall configuration of an elevator hall power supply device 1 according to Embodiment 1. As shown in FIG. As shown in FIG. 1, the elevator hall power supply device 1 includes a control panel 10, an operation display device 20 installed in the elevator hall of the N floor which is the top floor, and an operation display device 20 installed on the N floor. and a power supply box 30 that supplies the power. In addition, the elevator hall power supply device 1 includes an operation display device 40 installed in the elevator hall on the N−1 floor, which is one floor below the top floor, and an operation display device 40 installed on the N−1 floor. and a power supply box 50 capable of supplying

Furthermore, the elevator hall power supply device 1 is provided with an operation display device 60 installed in the elevator hall on the N-2 floor, which is two floors below the top floor, and an operation display device 60 installed on the N-2 floor. and a power supply box 70 capable of supplying

If the building in which the elevator is installed has four or more floors, the elevator hall on each floor below the N-2 floor is similarly provided with an operation display device and a power supply box (not shown). Also, the N floor may be a specific floor other than the top floor. In this case, the operation display device 40 and the power box 50 may be installed on the N+1 floor, which is one floor above the N floor. Similarly, the operation display device 60 and the power box 70 may be installed on the N+2 floor, which is two floors above the N floor.

The control panel 10 includes an AC power supply 11 that supplies AC power to the power supply boxes 30, 50, and 70 on each floor, and an operation control unit 12 that instructs the operation display devices 20, 40, and 60 on each floor. there is
The AC power supply source for the power supply boxes 30, 50, and 70 on each floor is not limited to the AC power supply 11 installed in the control panel 10, and may be, for example, an AC power supply installed outside the control panel 10. may

The operation display device 20 is provided with an indicator 21 for displaying the floor of the elevator car, a speaker 22 for announcing the elevator hall, and a call button 23 for calling the elevator car. An operation display board 24 is incorporated in the operation display device 20, and a CPU (Central Processing Unit) 25 is mounted on the operation display board 24. As shown in FIG. The CPU 25 is provided with a current consumption estimating section 26 for estimating the current consumption of the operation display device 20 , and the current consumption estimating section 26 holds current consumption data 27 .
The power supply box 30 is mounted with an AC-DC power supply 31 that converts AC power to DC power.

The operation display device 40 is provided with an indicator 41 for displaying the floor of the elevator car, a speaker 42 for announcing the elevator hall, and a call button 43 for calling the elevator car. An operation display board 44 is incorporated in the operation display device 40, and a CPU 45 is mounted on the operation display board 44. As shown in FIG. The CPU 45 is provided with a current consumption estimating section 46 for estimating the current consumption of the operation display device 40 and a switch control section 47 for selecting a power supply source of DC power. Current consumption data 48 is held in the current consumption estimator 46 .
The power supply box 50 incorporates an AC-DC power supply 51 that converts AC power into DC power, and a branch board 52 that switches the supply source of the DC power supplied to the operation display board 44 .

Similarly, the operation display device 60 is provided with an indicator 61 for displaying the floor of the elevator car, a speaker 62 for announcing the elevator hall, and a call button 63 for calling the elevator car. An operation display board 64 is incorporated in the operation display device 60, and a CPU 65 is mounted on the operation display board 64. As shown in FIG. The CPU 65 is provided with a consumption current estimating section 66 for estimating the consumption current of the operation display device 60 and a switch control section 67 for selecting the power source of the DC power supply source. Current consumption data 68 is held in the current consumption estimator 66 .
The power supply box 70 incorporates an AC-DC power supply 71 that converts AC power into DC power, and a branch board 72 that switches the supply source of the DC power supplied to the operation display board 64 .

LED lamps are built in the call buttons 23, 43, 63 of each floor, and when the call buttons 23, 43, 63 are pressed, the LED lamps light up until the elevator car arrives. By lighting the LED lamp, each user can know that the elevator car will stop at the floor where the user is located.

Also, the current consumption data 27, 48, 68 are, for example,
・Display "1" on the indicator: 0.2A
・Display "21" on the indicator: 0.5A
・Display "22" on the indicator: 0.6A
・Turn on the LED lamp of the call button: 0.5A
・Speaker announcement: 0.3A
Such data. Here, the reason why the current consumption data for displaying the number of floors on the indicator differs between "1", "21", and "22" is that the current consumption differs depending on the number of lit LEDs for dot matrix display.

In addition to the indicators 21, 41, 61, the speakers 22, 42, 62, and the call buttons 23, 43, 63, the operation display devices 20, 40, 60 are provided with motion sensors for detecting the presence or absence of the user. may have been

The AC power supply 11 and each of the plurality of AC-DC power supplies 31, 51, 71 are connected in parallel by an AC power line 80, and AC power is supplied from the AC power supply 11 to each of the AC-DC power supplies 31, 51, 71. . The AC-DC power supply 31 and the operation display board 24 are connected by a DC power line 81 , and the DC power converted by the AC-DC power supply 31 is supplied to the operation display board 24 .

On the other hand, each of the AC-DC power sources 31 and 51 and the operation display board 44 are connected by a DC power line 81 . A DC power line 81 between the operation display board 44 and the AC-DC power supply 31 includes a first switch 53 for switching on and off, and a first switch 53 for passing current only in the direction from the AC-DC power supply 31 to the operation display board 44. A diode 54 is provided. In addition, the DC power line 81 between the operation display board 44 and the AC-DC power supply 51 has a second switch 55 for switching on and off, and a second switch 55 for passing current only in the direction from the AC-DC power supply 51 to the operation display board 44 . 2 diodes 56 are provided.

The first switch 53 and the second switch 55 are controlled by the switch control unit 47 so that when one of them is on, the other is off. - selected from either a DC power supply 31 or an AC-DC power supply 51;
Here, part of the DC power line 81 is formed on the branch substrate 52, and on the DC power line 81 formed on the branch substrate 52, there are a first switch 53, a first diode 54, a second switch 55 and a second switch. A diode 56 is implemented.

When switching the switch to be turned on by controlling the first switch 53 and the second switch 55, the switch control unit 47 turns on the switch that was off and after both switches are turned on once, , to turn off the switch that was on. By controlling in this manner, the direct current supply to the operation display board 44 is not interrupted, and the operation display device 40 can be stably operated.

Next, each of the AC-DC power sources 31, 51, 71 and the operation display board 64 are connected by a DC power line 81. FIG. A DC power line 81 between the operation display board 64 and the AC-DC power supplies 31 and 51 has a first switch 73 for switching on and off, and a current flowing only in the direction from the AC-DC power supplies 31 and 51 to the operation display board 64. A first diode 74 is provided to pass through. In addition, the DC power line 81 between the operation display board 64 and the AC-DC power supply 71 has a second switch 75 for switching on and off, and a second switch 75 for passing current only in the direction from the AC-DC power supply 71 to the operation display board 64. 2 diodes 76 are provided.

The first switch 73 and the second switch 75 are controlled by the switch control unit 67 so that when one of them is on, the other is off. Either the DC power supply 31, 51 or the AC-DC power supply 71 is selected.
Here, part of the DC power line 81 is formed on the branch substrate 72, and on the DC power line 81 formed on the branch substrate 72, there are a first switch 73, a first diode 74, a second switch 75 and a second switch. A diode 76 is implemented.

When switching the switches to be turned on by controlling the first switch 73 and the second switch 75, the switch control unit 67 turns on the switches that were off and after both switches are turned on once. , to turn off the switch that was on. By controlling in this manner, the direct current supply to the operation display board 64 is not interrupted, and the operation display device 60 can be stably operated.

The operation control section 12 and the CPUs 25 , 45 and 65 are connected to each other via a signal line 82 . Therefore, communication can be performed between the control panel 10 and the CPUs 25, 45, 65 via the signal line 82 respectively.

FIG. 2 is a diagram showing the relationship between the power factor of the AC-DC power supplies 31, 51, 71 and the output current. As shown in FIG. 2, the AC-DC power supplies 31, 51, and 71 have a lower power factor as the output current decreases, regardless of whether the voltage is 100V, 200V, or 230V. Therefore, if the current consumption of the operation display devices 20, 40, 60 is less than the rated output current (for example, 1.0 A) of the AC-DC power supplies 31, 51, 71, power is wasted. becomes.

Therefore, when the current consumption of the operation display devices 20, 40, 60 on each floor is high, power is supplied to the operation display devices 20, 40, 60 from the AC-DC power sources 31, 51, 71 installed on each floor. However, when the current consumption is small, the power supply line is switched so that power is supplied from one AC-DC power supply to a plurality of operation display devices. In this way, the AC-DC power supply that has switched the power supply line to become the power supply source can supply power in a high power factor region. As a result, the elevator hall power supply device 1 according to the present embodiment can achieve high energy saving performance.

***Description of operation***
Next, the operation of the elevator hall power supply device 1 according to this embodiment will be described.
First, the operation of the control panel 10 will be described based on the flow chart of FIG. As shown in FIG. 3, the operation control unit 12 of the control panel 10 collects various information (step S10). The information includes operational information of the elevator car, information indicating that any one of the call buttons 23, 43, 63 of each floor has been pressed. The operation control unit 12 creates instruction information for instructing an operation based on the collected information, and transmits the created instruction information to the operation display devices 20, 40, 60 on each floor via the signal line 82 (step S11). .

The instruction information includes information instructing the indicators 21, 41, and 61 to display the floor number of the elevator car passing through, and instructing the speakers 22, 42, and 62 of the floor where the elevator car has arrived to play an arrival announcement. and information for instructing the call button 23, 43, 63 pressed by the user to turn on the LED lamp.
Further, when differential current data is received from any one of the operation display devices 20, 40, 60 on each floor, the operation control unit 12 transmits the received differential current data to the operation display devices 20, 40, 60 on the next floor. Data is transmitted (step S12). Here, the difference current data refers to the data of the current value obtained by subtracting the current consumption value of the operation display device from the rated output current value of the AC-DC power supply.
The processing of steps S10 to S12 is periodically repeated.

Next, the operation of the operation display device 20 installed in the elevator hall of the Nth floor, which is the top floor, will be described based on the flowchart of FIG. As shown in FIG. 4, the CPU 25 of the operation display device 20 receives instruction information transmitted by the operation control section 12 of the control panel 10 (step S20). The CPU 25 operates the indicator 21, the speaker 22, etc. based on the received instruction information (step S21). For example, if the instruction information is information instructing the indicator 21 to display the number of floors that the elevator car passes through, the indicator 21 is caused to display the number of floors that the elevator car passes through.
Further, when the call button 23 is pressed by the user, the CPU 25 transmits information indicating that there is a "platform call" to the operation control section 12 of the control panel 10 via the signal line 82 (step S22). .

Next, the current consumption estimator 26 extracts the current consumption value of the operation display device 20 based on the instruction information received in step S20 and the current consumption data 27 held by itself (step S23). A specific method of extracting the current consumption value will be described later. The current consumption estimator 26 subtracts the current consumption value extracted in step S23 from the rated output current value of the AC-DC power supply 31 stored in advance in the CPU 25, uses the subtraction result as differential current data, and outputs the signal line 82. to the operation control section 12 of the control panel 10 (step S24).

Next, the operation of the operation display device 40 installed in the elevator hall on the N-1 floor, which is one floor below the top floor, will be described with reference to the flow chart of FIG. As shown in FIG. 5, the CPU 45 of the operation display device 40 receives instruction information transmitted by the operation control section 12 of the control panel 10 (step S30). The CPU 45 also receives differential current data transmitted by the operation control section 12 of the control panel 10 (step S31). Furthermore, when the call button 43 is pressed by the user, the CPU 45 transmits information indicating that there is a "platform call" to the operation control section 12 of the control panel 10 via the signal line 82 (step S32). .

Next, the current consumption estimation unit 46 extracts the current consumption value of the operation display device 40 based on the instruction information received in step S30 and the current consumption data 48 held by itself (step S33). A specific method of extracting the current consumption value will be described later. The switch control unit 47 compares the differential current value indicated by the differential current data received in step S31 with the current consumption value extracted in step S33 (step S34).

When the differential current value is equal to or greater than the current consumption value, the switch control unit 47 turns on the first switch 53 and turns on the second switch 53 so as to receive power from the AC-DC power supply 31 installed on the N floor. switch 55 is turned off (step S35).
The CPU 45 operates the indicator 41, the speaker 42, etc. based on the instruction information received in step S30 (step S36). As a result, the indicator 41, the speaker 42, etc. operate by being supplied with power from the AC-DC power supply 31. FIG.
The current consumption estimator 46 subtracts the current consumption value from the differential current value, and transmits the result of the subtraction as differential current data to the operation controller 12 of the control panel 10 via the signal line 82 (step S37).

Further, in the comparison process in step S34, if the difference current value is less than the current consumption value, the switch control unit 47 receives power supply from the AC-DC power supply 51 installed on the N−1 floor. switch 53 is turned off, and the second switch 55 is turned on (step S38).
The CPU 45 operates the indicator 41, the speaker 42, etc. based on the instruction information received in step S30 (step S39). As a result, the indicator 41, the speaker 42, etc. operate by being supplied with power from the AC-DC power supply 51. FIG.
The current consumption estimating unit 46 subtracts the current consumption value extracted in step S33 from the rated output current value of the AC-DC power supply 51 stored in advance in the CPU 45, uses the subtraction result as differential current data, and outputs the signal line 82. is sent to the operation control section 12 of the control panel 10 via the control panel 10 (step S40).

Note that the operation of the operation display device 60 installed in the elevator hall on the N-2nd floor, which is two floors below the top floor, is the same as in the flow chart of FIG. 5, so description thereof will be omitted.

***Explanation of specific examples***
Next, a specific example of the operation of the elevator hall power supply device 1 according to this embodiment will be described. Here, the rated output current values of the AC-DC power sources 31, 51, 71 on each floor are all 1.0 A, and the current consumption data 27, 48, 68 on each floor are the data described above.

(Specific example 1)
In a specific example 1, the case of displaying "22" on each of the indicators 21, 41 and 61 will be described with reference to the block diagram of FIG. 1 and the flow charts of FIGS.
When the elevator car is stopped at the 22nd floor, the operation control unit 12 of the control panel 10 collects this floor information (step S10), and the operation control unit 12 displays "22" on the indicator. Instruction information is transmitted to the operation display devices 20, 40, 60 (step S11).

The operation display device 20 on the Nth floor receives the instruction information transmitted from the operation control section 12 (step S20). The current consumption estimation unit 26 extracts the current consumption value of the operation display device 20 based on the received instruction information and the current consumption data 27 held by itself (step S23). Since the instruction information is "display "22" on the indicator", 0.6 A corresponding to "display "22" on the indicator" is extracted from the current consumption data 27 as its current consumption value.

The current consumption estimation unit 26 subtracts the current consumption value of 0.6 A from the rated output current value of 1.0 A, and transmits the subtraction result of 0.4 A to the operation control unit 12 of the control panel 10 as differential current data (step S24). . When receiving the differential current data, the operation control unit 12 transmits the differential current data to the operation display device 40 on the N-1 floor (step S12).
The operation display device 20 is always supplied with power from the AC-DC power supply 31, and "22" is displayed on the indicator 21 receiving the power supply (step S21).

The operation display device 40 on the N−1 floor receives the instruction information and the difference current data transmitted from the operation control section 12 (steps S30 and S31). The current consumption estimation unit 46 extracts the current consumption value of the operation display device 40 based on the received instruction information and the current consumption data 48 held by itself (step S33). Since the instruction information is "display "22" on the indicator", 0.6 A corresponding to "display "22" on the indicator" is extracted from the current consumption data 48 as its current consumption value.

The switch control unit 47 compares the differential current value of 0.4 A indicated by the differential current data with the current consumption value of 0.6 A (step S34). , turns on the second switch 55 (step S38).
As a result, power is supplied from the AC-DC power supply 51 to the operation display device 40, and "22" is displayed on the indicator 41 receiving the power supply (step S39).

The current consumption estimation unit 46 subtracts the current consumption value of 0.6 A from the rated output current value of 1.0 A, and transmits the subtraction result of 0.4 A to the operation control unit 12 of the control panel 10 as differential current data (step S40). . When receiving the differential current data, the operation control unit 12 transmits the differential current data to the operation display device 60 on the N-2 floor (step S12).

The operation display device 60 on the N-2 floor receives the instruction information and the difference current data transmitted from the operation control section 12 (steps S30 and S31). The current consumption estimation unit 66 extracts the current consumption value of the operation display device 60 based on the received instruction information and the current consumption data 68 held by itself (step S33). Since the instruction information is "display "22" on the indicator", 0.6 A corresponding to "display "22" on the indicator" is extracted from the current consumption data 68 as its current consumption value.

The switch control unit 67 compares the differential current value of 0.4 A indicated by the differential current data with the current consumption value of 0.6 A (step S34). , turns on the second switch 75 (step S38).
As a result, power is supplied from the AC-DC power supply 71 to the operation display device 60, and "22" is displayed on the indicator 61 receiving the power supply (step S39).

The current consumption estimation unit 66 subtracts the current consumption value of 0.6 A from the rated output current value of 1.0 A, and transmits the subtraction result of 0.4 A to the operation control unit 12 of the control panel 10 as differential current data (step S40). . When the operation control unit 12 receives the differential current data, it transmits the differential current data to the operation display device (not shown) on the N-2 floor one floor below (step S12).

By the above operation, as shown in the block diagram of FIG. 1, the operation display device 20 is supplied with power from the AC-DC power supply 31, and the operation display device 40 is supplied with power from the AC-DC power supply 51. , the operation display device 60 is supplied with power from an AC-DC power source 71 .
In this way, the current consumption value of each operation display device 20, 40, 60 is grasped before the operation display device 20, 40, 60 operates, and the AC-DC power sources 31, 51, 71 of the power supply sources are allocated. Therefore, control can be performed without exceeding the supply capacity of the power supply.

(Specific example 2)
In a specific example 2, the case of displaying "1" on each of the indicators 21, 41 and 61 will be described with reference to the block diagram of FIG. 6 and the flow charts of FIGS.
When the elevator car is stopped on the first floor, the operation control unit 12 of the control panel 10 collects this floor information (step S10), and the operation control unit 12 displays "1" on the indicator. Instruction information is transmitted to the operation display devices 20, 40, 60 (step S11).

The operation display device 20 on the Nth floor receives the instruction information transmitted from the operation control section 12 (step S20). The current consumption estimation unit 26 extracts the current consumption value of the operation display device 20 based on the received instruction information and the current consumption data 27 held by itself (step S23). Since the instruction information is "display "1" on the indicator", 0.2 A corresponding to "display "1" on the indicator" is extracted from the current consumption data 27 as its current consumption value.

The current consumption estimation unit 26 subtracts the current consumption value of 0.2 A from the rated output current value of 1.0 A, and transmits the subtraction result of 0.8 A to the operation control unit 12 of the control panel 10 as differential current data (step S24). . When receiving the differential current data, the operation control unit 12 transmits the differential current data to the operation display device 40 on the N-1 floor (step S12).
The operation display device 20 is always supplied with power from the AC-DC power supply 31, and "1" is displayed on the indicator 21 receiving the power supply (step S21).

The operation display device 40 on the N−1 floor receives the instruction information and the difference current data transmitted from the operation control section 12 (steps S30 and S31). The current consumption estimation unit 46 extracts the current consumption value of the operation display device 40 based on the received instruction information and the current consumption data 48 held by itself (step S33). Since the instruction information is "display "1" on the indicator", 0.2 A corresponding to "display "1" on the indicator" is extracted from the current consumption data 48 as its current consumption value.

The switch control unit 47 compares the difference current value of 0.8 A indicated by the difference current data with the current consumption value of 0.2 A (step S34). , the second switch 55 is turned off (step S35).
As a result, power is supplied from the AC-DC power supply 31 to the operation display device 40, and "1" is displayed on the indicator 41 receiving power supply (step S36).

The current consumption estimator 46 subtracts the current consumption value of 0.2 A from the current difference value of 0.8 A, and transmits the subtraction result of 0.6 A as difference current data to the operation control unit 12 of the control panel 10 (step S37). When receiving the differential current data, the operation control unit 12 transmits the differential current data to the operation display device 60 on the N-2 floor (step S12).

The operation display device 60 on the N-2 floor receives the instruction information and the difference current data transmitted from the operation control section 12 (steps S30 and S31). The current consumption estimation unit 66 extracts the current consumption value of the operation display device 60 based on the received instruction information and the current consumption data 68 held by itself (step S33). Since the instruction information is "display "1" on the indicator", 0.2 A corresponding to "display "1" on the indicator" is extracted from the current consumption data 68 as its current consumption value.

The switch control unit 67 compares the difference current value of 0.6 A indicated by the difference current data with the current consumption value of 0.2 A (step S34), and since the difference current value is larger, the first switch 73 is turned on. , the second switch 75 is turned off (step S35).
As a result, power is supplied from the AC-DC power supply 31 to the operation display device 60, and "1" is displayed on the indicator 61 that receives the power supply (step S36).

The current consumption estimating unit 66 subtracts the current consumption value of 0.2 A from the current difference value of 0.6 A, and transmits the subtraction result of 0.4 A as difference current data to the operation control unit 12 of the control panel 10 (step S37). When the operation control unit 12 receives the differential current data, it transmits the differential current data to the operation display device (not shown) on the N-2 floor one floor below (step S12).

By the above operation, power is supplied from the AC-DC power supply 31 to all of the operation display devices 20, 40, 60 as shown in the block diagram of FIG.
Here, as shown in FIG. 1, when power is supplied from different AC-DC power sources 31, 51, 71 to each of the operation display devices 20, 40, 60, the rated output of the AC-DC power sources 31, 51, 71 Since the current consumption of the operation display devices 20, 40, 60 is less than the current, the power factor of each AC-DC power supply 31, 51, 71 is lowered as described with reference to FIG. will be consumed. In Specific Example 2, since power is supplied from the AC-DC power supply 31 to all of the operation display devices 20, 40, and 60, power can be supplied in a region where the power factor of the AC-DC power supply 31 is high. High energy saving performance can be obtained.

(Specific example 3)
In specific example 3, the block diagram of FIG. 7 and the flowcharts of FIGS. will be used for explanation.
As described specifically in Example 2 with reference to FIG. 6, the AC-DC power supply 31 is applied to all of the operation display devices 20, 40, and 60 before the Nth floor call button 23 is pressed. Power is supplied from
In this state, when the Nth floor call button 23 is pressed, the current consumption estimating unit 26 transmits information indicating that there is a "platform call" to the operation control unit 12 of the control panel 10 (step S22). . Upon receiving this information, the operation control unit 12 transmits information instructing the call button 23 to turn on the LED lamp to the operation display device 20 on the Nth floor (step S11).

The current consumption estimation unit 26 extracts the current consumption value of the operation display device 20 based on the received instruction information and the current consumption data 27 held by itself (step S23). Since the instruction information is "display "1" on the indicator" and "illuminate the LED lamp of the call button", 0.2 A corresponding to "display "1" on the indicator" and "call button 0.5 A corresponding to "lighting of the LED lamp" is extracted, and 0.7 A obtained by adding these current values is taken as the own current consumption value.

The current consumption estimation unit 26 subtracts the current consumption value of 0.7 A from the rated output current value of 1.0 A, and transmits the subtraction result of 0.3 A to the operation control unit 12 of the control panel 10 as differential current data (step S24). . When receiving the differential current data, the operation control unit 12 transmits the differential current data to the operation display device 40 on the N-1 floor (step S12).
The operation display device 20 is always supplied with power from the AC-DC power supply 31, and "1" is displayed on the indicator 21 receiving the power supply. Also, the LED lamp of the call button 23 lights up (step S21).

The operation display device 40 on the N−1 floor receives the instruction information and the difference current data transmitted from the operation control section 12 (steps S30 and S31). The current consumption estimation unit 46 extracts the current consumption value of the operation display device 40 based on the received instruction information and the current consumption data 48 held by itself (step S33). Since the instruction information is "display "1" on the indicator", 0.2 A corresponding to "display "1" on the indicator" is extracted from the current consumption data 48 as its current consumption value.

The switch control unit 47 compares the difference current value of 0.3 A indicated by the difference current data with the current consumption value of 0.2 A (step S34), and since the difference current value is larger, the first switch 53 is turned on. , the second switch 55 is turned off (step S35).
As a result, power is supplied from the AC-DC power supply 31 to the operation display device 40, and "1" is displayed on the indicator 41 receiving power supply (step S36).

The current consumption estimation unit 46 subtracts the current consumption value of 0.2 A from the current difference value of 0.3 A, and transmits the subtraction result of 0.1 A as difference current data to the operation control unit 12 of the control panel 10 (step S37). When receiving the differential current data, the operation control unit 12 transmits the differential current data to the operation display device 60 on the N-2 floor (step S12).

The operation display device 60 on the N-2 floor receives the instruction information and the difference current data transmitted from the operation control section 12 (steps S30 and S31). The current consumption estimation unit 66 extracts the current consumption value of the operation display device 60 based on the received instruction information and the current consumption data 68 held by itself (step S33). Since the instruction information is "display "1" on the indicator", 0.2 A corresponding to "display "1" on the indicator" is extracted from the current consumption data 68 as its current consumption value.

The switch control unit 67 compares the differential current value of 0.1 A indicated by the differential current data with the current consumption value of 0.2 A (step S34). , turns on the second switch 75 (step S38).
As a result, power is supplied from the AC-DC power supply 71 to the operation display device 60, and "1" is displayed on the indicator 61 receiving the power supply (step S39).

The current consumption estimation unit 66 subtracts the current consumption value of 0.2 A from the rated output current value of 1.0 A, and transmits the subtraction result of 0.8 A to the operation control unit 12 of the control panel 10 as differential current data (step S40). . When the operation control unit 12 receives the differential current data, it transmits the differential current data to the operation display device (not shown) on the N-2 floor one floor below (step S12).

As a result of the above operation, as shown in the block diagram of FIG. 7, the operation display devices 20 and 40 continue to be supplied with power from the AC-DC power supply 31, but the power supply source for the operation display device 60 is , the AC-DC power supply 31 is switched to the AC-DC power supply 71 .
Here, when the LED lamp of the call button 23 lights up, it becomes impossible to operate all of the operation display devices 20, 40, 60 only by supplying power from the AC-DC power supply 31. FIG. In the specific example 3, the power supply source for the operation display device 60 is changed from the AC-DC power supply 31 to the AC-DC power supply 71, so control can be performed without exceeding the power supply capacity.

(Specific example 4)
In specific example 4, the block diagram of FIG. 8 and the block diagram of FIG. A description will be given with reference to the flow chart of FIG.
When "22" is displayed on each indicator 21, 41, 61, as shown in FIG. Power is supplied from the DC power supply 51 and the operation display device 60 is supplied with power from the AC-DC power supply 71 .

In this state, when the elevator car moves from the 22nd floor to the 21st floor, the operation control unit 12 of the control panel 10 collects this movement information (step S10), and the operation control unit 12 outputs "21" to the indicator. display" is sent to the operation display device 20, 40, 60 (step S11).

The operation display device 20 on the Nth floor receives the instruction information transmitted from the operation control section 12 (step S20). The current consumption estimation unit 26 extracts the current consumption value of the operation display device 20 based on the received instruction information and the current consumption data 27 held by itself (step S23). Since the instruction information is "display "21" on the indicator", 0.5 A corresponding to "display "21" on the indicator" is extracted from the current consumption data 27 as its current consumption value.

The current consumption estimation unit 26 subtracts the current consumption value of 0.5 A from the rated output current value of 1.0 A, and transmits the subtraction result of 0.5 A to the operation control unit 12 of the control panel 10 as differential current data (step S24). . When receiving the differential current data, the operation control unit 12 transmits the differential current data to the operation display device 40 on the N-1 floor (step S12).
The operation display device 20 is always supplied with power from the AC-DC power supply 31, and "21" is displayed on the indicator 21 receiving the power supply (step S21).

The operation display device 40 on the N−1 floor receives the instruction information and the difference current data transmitted from the operation control section 12 (steps S30 and S31). The current consumption estimation unit 46 extracts the current consumption value of the operation display device 40 based on the received instruction information and the current consumption data 48 held by itself (step S33). Since the instruction information is "display "21" on the indicator", 0.5 A corresponding to "display "21" on the indicator" is extracted from the current consumption data 48 as its current consumption value.

The switch control unit 47 compares the differential current value of 0.5 A indicated by the differential current data with the consumption current value of 0.5 A (step S34). 2 switch 55 is turned off (step S35).
As a result, power is supplied from the AC-DC power supply 31 to the operation display device 40, and "21" is displayed on the indicator 41 receiving the power supply (step S36).

The current consumption estimator 46 subtracts the current consumption value of 0.5 A from the current difference value of 0.5 A, and transmits the subtraction result of 0.0 A to the operation control unit 12 of the control panel 10 as difference current data (step S37). When receiving the differential current data, the operation control unit 12 transmits the differential current data to the operation display device 60 on the N-2 floor (step S12).

The operation display device 60 on the N-2 floor receives the instruction information and the difference current data transmitted from the operation control section 12 (steps S30 and S31). The current consumption estimation unit 66 extracts the current consumption value of the operation display device 60 based on the received instruction information and the current consumption data 68 held by itself (step S33). Since the instruction information is "display "21" on the indicator", 0.5 A corresponding to "display "21" on the indicator" is extracted from the current consumption data 68 as its current consumption value.

The switch control unit 67 compares the differential current value of 0.0 A indicated by the differential current data with the current consumption value of 0.5 A (step S34). , turns on the second switch 75 (step S38).
As a result, power is supplied from the AC-DC power supply 71 to the operation display device 60, and "21" is displayed on the indicator 61 receiving the power supply (step S39).

The current consumption estimation unit 66 subtracts the current consumption value of 0.5 A from the rated output current value of 1.0 A, and transmits the subtraction result of 0.5 A to the operation control unit 12 of the control panel 10 as difference current data (step S40). . When the operation control unit 12 receives the differential current data, it transmits the differential current data to the operation display device (not shown) on the N-2 floor one floor below (step S12).

By the above operation, as shown in the block diagram of FIG. 8, the operation display device 20 is continuously supplied with power from the AC-DC power supply 31, and the operation display device 60 is supplied with power from the AC-DC power supply 71. However, the source of power supply to the operation display device 40 switches from the AC-DC power supply 51 to the AC-DC power supply 31 .
Here, when the display of the indicators 21, 41, 61 switches from "22" to "21", the current consumption value of each of the operation display devices 20, 40, 60 changes from 0.6A to 0.5A. For this reason, as shown in FIG. The power factor will be low, and power will be wasted as described with reference to FIG. In Specific Example 4, since power is supplied from the AC-DC power source 31 to the operation display device 20 and the operation display device 40, power can be supplied in a region where the power factor of the AC-DC power source 31 is high. Energy saving performance can be obtained.

Note that, as shown in step S24, the difference current value is a value obtained by subtracting the current consumption value of the operation display device 20 from the rated output current value of the AC-DC power supply 31. FIG. For this reason, the content of the judgment in step S34, "differential current value≧consumed current value", is based on the comparison formula, "rated output current value of AC-DC power supply 31−consumption current value of operation display device 20≧current consumption of operation display device 40. is equivalent to "value". Here, if the "current consumption value of the operation display device 20" is added to both sides of this comparison formula, the formula "rated output current value of the AC-DC power supply 31 ≥ current consumption value of the operation display device 20 + operation display device 40 It can be said that it is equivalent to the current consumption value of

Therefore, when the rated output current value of the AC-DC power supply 31 is equal to or greater than the sum of the current consumption values of the operation display device 20 and the operation display device 40, the switch control unit 47 controls the AC-DC power supply The first switch 53 and the second switch 55 are controlled to select 31, and the rated output current value of the AC-DC power supply 31 is the current consumption value of the operation display device 20 and the current consumption value of the operation display device 40. It can also be said that the first switch 53 and the second switch 55 are controlled to select the AC-DC power source 51 when the total value of .

Similarly, the switch control unit 67 determines that the rated output current value of the AC-DC power supply 31 is the sum of the current consumption value of the operation display device 20, the current consumption value of the operation display device 40, and the current consumption value of the operation display device 60. In the above case, the first switch 73 and the second switch 75 are controlled to select the AC-DC power supply 31, and the rated output current value of the AC-DC power supply 31 is the current consumption value of the operation display device 20. and the sum of the current consumption value of the operation display device 40 and the current consumption value of the operation display device 60, the first switch 73 and the second switch 75 are turned to select the AC-DC power supply 71. It is also possible to control.

*** Effect of Embodiment 1 ***
As described above, the elevator hall power supply device 1 according to Embodiment 1 includes the current consumption estimating unit 26 for estimating the current consumption value of the operation display device 20 and the current consumption estimation unit 26 for estimating the current consumption value of the operation display device 40. and a first switch 53 for selecting either the AC-DC power supply 31 or the AC-DC power supply 51 based on the current consumption value of the operation display device 20 and the current consumption value of the operation display device 40. and a switch control unit 47 that controls the second switch 55 .

Here, since the current consumption estimation units 26 and 46 estimate the current consumption of the operation display devices 20 and 40 before the operation display devices 20 and 40 actually operate, each operation display device 20 and 40 needs It is possible to grasp in advance the amount of DC power to be supplied. The switch control unit 47 controls the first switch 53 and the second switch 55 based on the estimated current consumption.
In this manner, the switch control unit 47 grasps in advance the amount of DC power to be supplied when the operation display devices 20 and 40 are actually operated, and then the AC-DC power supply 31 and the AC-DC power supply 51 are switched. Since the first switch 53 and the second switch 55 are controlled so as to select either one, optimum AC-DC power supply allocation becomes possible.

Further, when the difference current value obtained by subtracting the current consumption value of the operation display device 20 from the rated output current value of the AC-DC power supply 31 is greater than or equal to the current consumption value of the operation display device 40, the switch control unit 47 The first switch 53 and the second switch 55 are controlled to select the DC power supply 31, and when the difference current value is less than the current consumption value of the operation display device 40, the AC-DC power supply 51 is selected. , the first switch 53 and the second switch 55 are controlled.

Therefore, when the current consumption value of the operation display device 40 is less than the differential current value, the switch control unit 47 selects the AC-DC power source 31 instead of the AC-DC power source 51 as the source of power supply to the operation display device 40. The first switch 53 and the second switch 55 are controlled so that With this control, power is supplied from the AC-DC power source 31 to each of the operation display device 20 and the operation display device 40, so power can be supplied in a region where the power factor of the AC-DC power source 31 is high. In this manner, the elevator hall power supply device 1 according to Embodiment 1 can suppress wasteful power consumption, and can obtain high energy saving performance.

Furthermore, the current consumption estimating units 26 and 46 estimate the current consumption values of the operation display devices 20 and 40 based on the instruction information transmitted from the operation control unit 12 and the current consumption data 27 and 48 held by themselves. are doing. As described above, the current consumption values of the operation display devices 20 and 40 are estimated based on the instruction information collected by the operation control unit 12, so that each operation display device 20 and 40 needs to collect the instruction information individually. and efficient processing can be performed.

In addition, current consumption data 27 and 48 held by the respective current consumption estimation units 26 and 46 are used in the estimation of the current consumption values of the operation display devices 20 and 40 by the current consumption estimation units 26 and 46 . Therefore, even if the indicators 21, 41, 61, etc. provided on the respective operation display devices 20, 40 are replaced, the updated information can be fully reflected in the current consumption data 27, 48. . Therefore, the current consumption value can be estimated with high accuracy.

Furthermore, the elevator hall power supply device 1 according to Embodiment 1 includes a current consumption estimating unit 66 for estimating the current consumption value of the operation display device 60, the current consumption value of the operation display device 20 and the current consumption value of the operation display device 40. and the current consumption value of the operation display device 60, the first switch 73 and the second switch 75 are controlled to select either the AC-DC power supply 31 or the AC-DC power supply 71. 67.

Here, since the current consumption estimator 66 estimates the current consumption value of the operation display device 60 before the operation display device 60 actually operates, the DC power required by the operation display devices 20, 40, 60 is It is possible to know in advance the amount of supply of The switch control unit 67 controls the first switch 73 and the second switch 75 based on the estimated current consumption value.
In this way, the switch control unit 67 grasps in advance the amount of DC power to be supplied when the operation display devices 20, 40, and 60 are actually operated, and then the AC-DC power supply 31 and the AC-DC power supply. Since the first switch 73 and the second switch 75 are controlled to select either one of 71, optimum AC-DC power allocation is possible.

Further, the switch control unit 67 subtracts the current consumption value of the operation display device 20 and the current consumption value of the operation display device 40 from the rated output current value of the AC-DC power supply 31, and the second difference current value is the operation display device. 60, the first switch 73 and the second switch 75 are controlled to select the AC-DC power supply 31, and the second difference current value is the current consumption of the operation display device 60. If it is less than the value, it controls the first switch 73 and the second switch 75 to select the AC-DC power supply 71 .

Therefore, when the current consumption value of the operation display device 60 is less than the differential current value, the switch control unit 67 selects the AC-DC power source 31 instead of the AC-DC power source 71 as the source of power supply to the operation display device 60. The first switch 73 and the second switch 75 are controlled so that With this control, power is supplied from the AC-DC power supply 31 to each of the operation display device 20, the operation display device 40, and the operation display device 60, so power is supplied in a region where the power factor of the AC-DC power source 31 is high. becomes possible. In this manner, the elevator hall power supply device 1 according to Embodiment 1 can suppress wasteful power consumption, and can obtain high energy saving performance.

Hereinafter, various aspects of the present disclosure will be collectively described as appendices.

(Appendix 1)
An elevator hall power supply device that supplies power to operation display devices respectively installed in a plurality of halls,
a first power supply unit that supplies DC power to a first operation display device installed in a first hall among the plurality of halls;
a second power supply unit capable of supplying DC power to a second operation display device installed in a second hall among the plurality of halls;
a first current consumption estimating unit that estimates a current consumption value of the first operation display device;
a second current consumption estimator for estimating a current consumption value of the second operation display device;
a selection switch for selecting a supply source of DC power from either the first power supply unit or the second power supply unit to the second operation display device;
Based on the current consumption value of the first operation display device estimated by the first current consumption estimation unit and the current consumption value of the second operation display device estimated by the second current consumption estimation unit, An elevator hall power supply device comprising a switch control section for controlling the selection switch to select either the first power supply section or the second power supply section.
(Appendix 2)
When the differential current value obtained by subtracting the current consumption value of the first operation display device from the rated output current value of the first power supply unit is equal to or greater than the current consumption value of the second operation display device, the switch control unit the selection switch is controlled to select the first power supply unit, and when the difference current value is less than the current consumption value of the second operation display device, the second power supply unit is selected 2. The elevator hall power supply of claim 1, wherein the selector switch is controlled to select.
(Appendix 3)
further comprising an operation control unit that instructs an operation to the first operation display device and the second operation display device;
The elevator hall power supply according to Supplementary note 1 or Supplementary note 2, wherein the first current consumption estimating unit and the second current consumption estimating unit estimate a current consumption value based on instruction information respectively transmitted from the operation control unit. Device.
(Appendix 4)
The first current consumption estimating unit and the second current consumption estimating unit each include current consumption data, and the first current consumption estimating unit and the second current consumption estimating unit receive current consumption data from the operation control unit. 3. The elevator hall power supply device according to appendix 3, wherein the current consumption value is estimated from the transmitted instruction information and the current consumption data.
(Appendix 5)
The selection switch includes a first switch provided on a power line that supplies DC power from the first power supply unit, and a second switch provided on a power line that supplies DC power from the second power supply unit. a switch;
The first switch and the second switch are controlled so that when one of them is on, the other is off. 5. The elevator hall power supply device according to any one of appendices 1 to 4, which turns off the switch that was on after being turned on.
(Appendix 6)
a third power supply unit capable of supplying DC power to a third operation display device installed in a third hall among the plurality of halls;
a third current consumption estimator for estimating a current consumption value of the third operation display device;
a second selection switch for selecting a supply source of DC power from either the first power supply section or the third power supply section to the third operation display device;
The current consumption value of the first operation display device estimated by the first current consumption estimation unit, the current consumption value of the second operation display device estimated by the second current consumption estimation unit, and the third current consumption value the second selection switch for selecting either the first power supply unit or the third power supply unit based on the current consumption value of the third operation display device estimated by the current consumption estimation unit; 6. The elevator hall power supply device according to any one of appendices 1 to 5, further comprising a second switch control unit that controls the
(Appendix 7)
The second switch control section subtracts the current consumption value of the first operation display device and the current consumption value of the second operation display device from the rated output current value of the first power supply section. is equal to or greater than the current consumption value of the third operation display device, the selection switch is controlled to select the first power supply section, and the second differential current value is equal to or greater than the third 6. The elevator hall power supply device according to Supplementary Note 6, wherein the selection switch is controlled to select the third power supply unit when the consumption current value of the operation display device of Item 3 is less than the current consumption value.
(Appendix 8)
The second selection switch includes a third switch provided on a power line that supplies DC power from the first power supply unit, and a power line that supplies DC power from the third power supply unit. a fourth switch;
The third switch and the fourth switch are controlled so that when one of them is on, the other is off. 8. The elevator hall power supply according to appendix 6 or appendix 7, which turns off the switch that was on after being turned on.
(Appendix 9)
A first power supply unit that supplies DC power to a first operation display device installed at a first landing, and a second power supply that can supply DC power to a second operation display device installed at a second landing. A power supply method in an elevator hall power supply device comprising a power supply unit of
estimating the current consumption value of the first operation display device and the current consumption value of the second operation display device, and calculating the estimated current consumption value of the first operation display device and the second operation display device; A power supply method for selecting a supply source of DC power from either the first power supply unit or the second power supply unit to the second operation display device based on the consumption current value of .

1 elevator hall power supply device, 10 control panel, 11 AC power supply, 12 operation control unit, 20 operation display device (first operation display device), 21, 41, 61 indicator, 22, 42, 62 speaker, 23, 43, 63 call button, 26 current consumption estimation unit (first current consumption estimation unit), 31 AC-DC power supply (first power supply unit), 40 operation display device (second operation display device), 46 current consumption estimation unit (Second Consumption Current Estimation Unit), 47 Switch Control Unit, 51 AC-DC Power Supply (Second Power Supply Unit), 53 First Switch (Selection Switch), 55 Second Switch (Selection Switch), 60 Operation Display instrument (third operation display instrument), 66 current consumption estimation unit (third current consumption estimation unit), 67 switch control unit (second switch control unit), 71 AC-DC power supply (third power supply unit ), 73 first switch (second selection switch), 75 second switch (second selection switch).

Claims (9)

An elevator hall power supply device that supplies power to operation display devices respectively installed in a plurality of halls,
a first power supply unit that supplies DC power to a first operation display device installed in a first hall among the plurality of halls;
a second power supply unit capable of supplying DC power to a second operation display device installed in a second hall among the plurality of halls;
a first current consumption estimating unit that estimates a current consumption value of the first operation display device;
a second current consumption estimator for estimating a current consumption value of the second operation display device;
a selection switch for selecting a supply source of DC power from either the first power supply unit or the second power supply unit to the second operation display device;
Based on the current consumption value of the first operation display device estimated by the first current consumption estimation unit and the current consumption value of the second operation display device estimated by the second current consumption estimation unit, An elevator hall power supply device comprising a switch control section for controlling the selection switch to select either the first power supply section or the second power supply section. When the differential current value obtained by subtracting the current consumption value of the first operation display device from the rated output current value of the first power supply unit is equal to or greater than the current consumption value of the second operation display device, the switch control unit the selection switch is controlled to select the first power supply unit, and when the difference current value is less than the current consumption value of the second operation display device, the second power supply unit is selected 2. The elevator hall power supply of claim 1, wherein the selector switch is controlled to select. further comprising an operation control unit that instructs an operation to the first operation display device and the second operation display device;
3. The elevator according to claim 1, wherein the first current consumption estimating section and the second current consumption estimating section estimate current consumption values based on instruction information respectively transmitted from the operation control section. Platform power supply. The first current consumption estimating unit and the second current consumption estimating unit each include current consumption data, and the first current consumption estimating unit and the second current consumption estimating unit receive current consumption data from the operation control unit. 4. The elevator hall power supply device according to claim 3, wherein a current consumption value is estimated from the transmitted instruction information and the current consumption data. The selection switch includes a first switch provided on a power line that supplies DC power from the first power supply unit, and a second switch provided on a power line that supplies DC power from the second power supply unit. a switch;
The first switch and the second switch are controlled so that when one of them is on, the other is off. 2. The elevator hall power supply according to claim 1, which turns off a switch that has been on after being turned on. a third power supply unit capable of supplying DC power to a third operation display device installed in a third hall among the plurality of halls;
a third current consumption estimator for estimating a current consumption value of the third operation display device;
a second selection switch for selecting a supply source of DC power from either the first power supply section or the third power supply section to the third operation display device;
The current consumption value of the first operation display device estimated by the first current consumption estimation unit, the current consumption value of the second operation display device estimated by the second current consumption estimation unit, and the third current consumption value the second selection switch for selecting either the first power supply unit or the third power supply unit based on the current consumption value of the third operation display device estimated by the current consumption estimation unit; 3. The elevator hall power supply device according to claim 1 or 2, further comprising a second switch control unit that controls the . The second switch control section subtracts the current consumption value of the first operation display device and the current consumption value of the second operation display device from the rated output current value of the first power supply section. is equal to or greater than the current consumption value of the third operation display device, the selection switch is controlled to select the first power supply section, and the second differential current value is equal to or greater than the third 7. The elevator hall power supply device according to claim 6, wherein the selection switch is controlled to select the third power supply section when the current consumption is less than the current consumption value of the operation display device of No. 3. The second selection switch includes a third switch provided on a power line that supplies DC power from the first power supply unit, and a power line that supplies DC power from the third power supply unit. a fourth switch;
The third switch and the fourth switch are controlled so that when one of them is on, the other is off. 7. The elevator hall power supply according to claim 6, which turns off the switch that was on after being turned on. A first power supply unit that supplies DC power to a first operation display device installed at a first landing, and a second power supply that can supply DC power to a second operation display device installed at a second landing. A power supply method in an elevator hall power supply device comprising a power supply unit of
estimating the current consumption value of the first operation display device and the current consumption value of the second operation display device, and calculating the estimated current consumption value of the first operation display device and the second operation display device; A power supply method for selecting a supply source of DC power from either the first power supply unit or the second power supply unit to the second operation display device based on the consumption current value of .

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