JP7257997B2 - elevator equipment - Google Patents

Description

The present invention relates to an elevator system.

In recent years, as a countermeasure against infectious diseases such as viruses in elevators, it has been desired to disinfect parts that are touched by people, such as operation buttons in the car. Patent Literature 1 describes a technique for sterilizing a push button in a car by installing an ultraviolet light emitting diode and sterilizing the push button with the ultraviolet light emitting diode after the push button is pressed.

JP 2011-143994 A

As described in U.S. Pat. No. 5,302,002, a mechanism for sterilizing destination floor registration push buttons located within elevator cars can be provided to automatically sterilize the push buttons.
However, when a mechanism for sterilizing push buttons with ultraviolet light emitting diodes is provided, in order to sufficiently sterilize (sterilize), it is necessary to continuously irradiate ultraviolet rays, which have a sterilizing effect, for a certain amount of time. It will take some time to complete. Therefore, in the case of an elevator with many users, the next user may touch the button before the sterilization process is completed, and the sterilization function may not function effectively.

On the other hand, as another mechanism for preventing infection by contact with viruses, etc., it has been proposed to place a non-contact button that can be operated without contact by bringing the user's finger close to the button inside the elevator car. ing. In the case of non-contact buttons, the user can indicate the destination floor without touching the buttons, which is highly effective in preventing infections caused by touching the buttons.

However, since there are very few elevators equipped with non-contact buttons at present, users are not accustomed to operating non-contact buttons, and some users may desire to operate with conventional push buttons. Therefore, even if non-contact buttons are placed on the car, considering user operability, conventional push buttons are also placed so that destination floors can be registered using both the push buttons and the non-contact buttons. It is desirable to
However, it is preferable to disinfect the push button as already explained, and if the push button and the non-contact button are used together, the infection prevention effect cannot be sufficiently achieved.

SUMMARY OF THE INVENTION It is an object of the present invention to provide an elevator device that effectively prevents users from being infected with viruses or the like.

In order to solve the above problems, for example, the configurations described in the claims are adopted.
The present application includes a plurality of means for solving the above problems. To give an example, an elevator device includes a first operation panel on which push buttons for registering a destination floor by user's touch operation are arranged. a second operation panel on which non-contact buttons for registering destination floors by user's non-contact operation are arranged; an operation panel signal acquisition unit for acquiring destination floor information from the first and second operation panels; A disinfection determination unit that instructs execution of disinfection when the operation panel signal acquisition unit detects an operation of a push button , a disinfection unit that disinfects the push button based on the disinfection execution instruction from the disinfection judgment unit, and a disinfection judgment and a notification unit that performs guidance for prompting an operation by a non-contact button by voice or display when an instruction to perform disinfection by the disinfection unit is given in the unit .

According to the present invention, operability can be ensured by arranging both the push button and the non-contact button, and when the push button needs to be disinfected, the user can be instructed to operate using the non-contact button. You will be able to guide and properly prevent infection.
Problems, configurations, and effects other than those described above will be clarified by the following description of the embodiments.

1 is a configuration diagram showing an example of the inside of a car of an elevator device according to an embodiment of the present invention; FIG. It is a block diagram which shows the structural example of the control apparatus with which the elevator apparatus by the example of one embodiment of this invention is provided. It is a block diagram which shows the hardware structural example of the control apparatus with which the elevator apparatus by the example of one embodiment of this invention is equipped. It is a flow chart which shows an example of a flow of destination floor registration processing by one example of an embodiment of the present invention. 4 is a flow chart showing the flow of determination processing in a disinfection determination unit according to an embodiment of the present invention; 4 is a flow chart showing an example of disinfection processing in a disinfection unit according to an embodiment of the present invention; 4 is a flow chart showing an example of processing based on determination by a failure determination unit according to an embodiment of the present invention; FIG. 10 is a diagram showing an example of the number of operations of a push button and a non-contact button according to one embodiment of the present invention;

An elevator apparatus according to an embodiment (hereinafter referred to as "this example") of the present invention will now be described with reference to the accompanying drawings.

[Construction of car]
FIG. 1 shows a configuration example of a car 101 provided in the elevator system of this example.
A door 102 is arranged in the car 101, and the door 102 opens when the car stops at each floor.
A first operation panel 110 is arranged on one side (right side in the figure) of the door 102, and a second operation panel 120 is arranged on the other side (left side in the figure).

Push buttons 111 are arranged on the first operation panel 110 as buttons for registering destination floors and for instructing the opening and closing of the doors 102 . The push button 111 is a button that is operated by the user pressing (touching) the push button 111 with a finger or the like.
A non-contact button 121 is arranged on the second operation panel 120 as a button for registering a destination floor and for instructing opening/closing of the door 102 . The non-contact button 121 is a button that incorporates a proximity sensor or the like and is operated by detecting the proximity of a user's finger or the like to the button surface.
The push buttons 111 and the non-contact buttons 121 are installed as many as the number of service floors of the building where the elevator device of this example is installed.

The elevator apparatus of this example registers the stop floor assigned to the operated button 111 or 121, regardless of whether the push button 111 or the non-contact button 121 is operated, and moves the car 101 to the corresponding floor. Perform the service to be stopped. However, as will be described later, when the push button 111 is disinfected, the operation of the push button 111 may be invalidated.

A display unit 103 and an announcement unit 104 are arranged above the first operation panel 110 . The display unit 103 and the announcement unit 104 function as a notification unit that guides passengers in the car 101 through display or voice output. The display unit 103 and the announcement unit 104 normally guide the floor to be stopped, the opening and closing of the door, and the like.

A disinfecting unit 105 is arranged adjacent to the first operation panel 110 . The disinfection section 105 disinfects the push buttons 111 arranged on the first operation panel 110 . Disinfection of the push button 111 by the disinfection unit 105 is performed according to an instruction from the disinfection determination unit 203 of the control device 200, which will be described later.

The disinfection unit 105 is equipped with, for example, an ultraviolet light emitting diode or an ultraviolet light emitting lamp that emits ultraviolet light, and emits ultraviolet light that has a sterilizing effect for a predetermined period of time, thereby disinfecting the surface of the push button 111 . Alternatively, the disinfecting unit 105 may disinfect the surface of the push button 111 by applying a disinfecting liquid such as alcohol to the push button 111 . Alternatively, the disinfection unit 105 may use both the emission of ultraviolet rays and the application of a disinfectant solution having a bactericidal action.

[Configuration of control device]
FIG. 2 shows the configuration of a control device 200 provided in the elevator system of this example.
The control device 200 includes a travel control unit 201 , a control panel signal acquisition unit 202 , a disinfection determination unit 203 , an abnormality determination unit 204 and a communication unit 205 .

The running control unit 201 controls running (lifting) of the car 101 .
The control panel signal acquisition unit 202 acquires registered floor information by operating the push button 111 arranged on the first operating panel 110 and registered floor information by operating the non-contact button 121 arranged on the second operating panel 120. to get The registered floor information acquired by the operating panel signal acquisition unit 202 is supplied to the running control unit 201 . The travel control unit 201 controls the stop floor of the car 101 based on the received registered floor information.

The disinfection determination unit 203 determines whether or not the push button 111 needs to be disinfected based on information from the operation panel signal acquisition unit 202 and the travel control unit 201 . The disinfection unit 105 disinfects the push button 111 based on the determination result of the disinfection determination unit 203 as to whether or not disinfection is necessary. Further, when the disinfection unit 105 executes disinfection of the push button 111 , notification processing of disinfection is performed by display on the display unit 103 and audio output by the announcement unit 104 . In addition, when the disinfection unit 105 executes disinfection according to an instruction from the disinfection determination unit 203, it confirms that the disinfection can be started, such as when the car 101 is not running and unmanned, as will be described later. Then start the disinfection process.

The abnormality determination unit 204 determines failure of the push button 111 and failure of the non-contact button 121 based on information from the operation panel signal acquisition unit 202 and the travel control unit 201 .
Based on the information from the abnormality determination unit 204, the communication unit 205 notifies an external control center (not shown) of the failure information.

FIG. 3 shows an example hardware configuration of the control device 200 . The example shown in FIG. 3 is an example in which the control device 200 is configured by a computer device.
A control device (computer device) 200 shown in FIG. 3 includes a CPU (Central Processing Unit) 211, a ROM (Read Only Memory) 212, and a RAM (Random Access Memory) 213, which are respectively connected to a bus. . Furthermore, the control device 200 includes a nonvolatile storage 214 , an input interface 215 , an output interface 216 and a communication section 205 .

The CPU 211 is an arithmetic processing unit that reads out from the ROM 212 and executes program codes of software for executing control processing in the control device 200 . The ROM 212 stores programs related to the travel control function and the disinfection function executed by the control device 200 .
The RAM 213 temporarily writes variables, parameters, and the like generated during arithmetic processing.

The nonvolatile storage 214 is, for example, a large-capacity information storage unit such as an HDD (Hard Disk Drive) or SSD (Solid State Drive). The nonvolatile storage 214 stores, for example, the number of past operations of the push button 111 and the non-contact button 121 .

The input interface 215 performs input processing for acquiring operation information of the push button 111 and the non-contact button 121 .
The output interface 216 performs output processing for outputting information and instructions to the display unit 103 , the announcement unit 104 and the disinfection unit 105 .
A communication unit 205 communicates with the outside such as a control center via a predetermined network.

It should be noted that the configuration of the control device 200 with the computer device shown in FIG. 3 is an example, and may be configured with an arithmetic processing device other than the computer device. For example, some or all of the functions performed by the control device 200 may be realized by hardware such as FPGA (Field Programmable Gate Array) or ASIC (Application Specific Integrated Circuit).

[Processing when registering a destination floor]
FIG. 4 is a flow chart showing an example of processing when the destination floor registration push button 111 and non-contact button 121 in the car 101 are operated in the elevator apparatus of this example.
First, the control device 200 determines whether or not the destination floor registration push button 111 has been operated (step S11). Here, if the destination floor registration push button 111 is operated (Yes in step S11), the travel control unit 201 acquires the operation information of the push button 111 acquired by the control panel signal acquisition unit 202 (step S12). . Then, the travel control unit 201 registers the destination floor based on the operation information acquired in step S12 (step S15).
Further, the traveling control unit 201 starts traveling to the registered destination floor (step S16), and ends the process.

If the push button 111 is not operated in step S11 (No in step S11), the control device 200 determines whether or not the non-contact button 121 for destination floor registration has been operated (step S13). . Here, when the non-contact button 121 for destination floor registration is operated (Yes in step S13), the travel control unit 201 obtains the operation information of the non-contact button 121 acquired by the control panel signal acquisition unit 202 ( Step S14), the processing of steps S15 and S16 described above is performed.

If the non-contact button 121 has not been operated in step S13 (No in step S13), the control device 200 returns to step S11 to determine whether the destination floor registration push button 111 has been operated.

[Processing when operating the disinfection part]
FIG. 5 is a flowchart showing an example of processing when the disinfection determination unit 203 operates the disinfection unit 105 when the push button 111 is operated.
First, the disinfection determination unit 203 confirms whether or not the push button 111 has been operated (step S21). In step S21, if there is an operation of the push button 111 (Yes in step S21), the disinfection determination unit 203 determines whether the car 101 is running with destination floor registration based on the operation of the push button 111. (Step S22).
When it is determined in step S21 that the push button 111 is not operated (No in step S21) and when it is determined in step S22 that the car 101 does not travel (No in step S22), the disinfection determination unit 203 It is determined that the disinfection of the push button 111 by is not necessary, and the processing of FIG. 5 ends.

Then, in step S22, when it is determined that the car 101 has run due to the destination floor registration by operating the push button 111 (Yes in step S22), and when the service by running to the destination floor has been completed, The disinfection determination unit 203 invalidates the destination floor registration operation by the push button 111 (step S23).
Then, when the destination floor registration operation by the push button 111 is invalidated, the announcement unit 104 and the display unit 103 output a voice saying, for example, "Only non-contact buttons can be used" according to instructions from the disinfection determination unit 203. and display (step S24). The voice output and display in step S24 are continued until the invalidation is cancelled.

Next, the disinfection determination unit 203 activates the disinfection unit 105, and the disinfection unit 105 disinfects the push button 111 (step S25). Details of the processing when the disinfection unit 105 operates will be described later with reference to FIG.
Then, the disinfection determination unit 203 determines whether the disinfection of the push button 111 by the disinfection unit 105 has been completed (step S26).

When it is determined in step S26 that the disinfection has been completed (Yes in step S26), the disinfection determination unit 203 cancels the invalidation of the push button 111 performed in step S23 (step S27). Then, the disinfection determination unit 203 stops the voice output and display of "only non-contact buttons are valid" started in step S24 (step S28). As a result, a series of processes during the disinfection operation by the disinfection unit 105 ends.

If it is determined in step S26 that the disinfection has not been completed (No in step S26), the process returns to step S24 to continue the voice output and display of "only non-contact buttons are valid".

[Disinfection processing by the disinfection unit]
FIG. 6 shows details of the disinfection process of the push button 111 by the disinfection unit 105 in step S25 of the flowchart of FIG. In the case of the elevator apparatus of this example, disinfection by the disinfection unit 105 is performed by irradiation of ultraviolet rays or application of a disinfectant solution, and these disinfection processes are performed when the car 101 is unmanned.
Therefore, the disinfection determination unit 203 determines whether or not the car 101 is running (step S31). If it is determined in step S31 that the car 101 is running (Yes in step S31), the disinfection determination unit 203 does not operate the disinfection unit 105 because there is a high possibility that the car 101 is not unoccupied.

Further, when it is determined in step S31 that the car 101 is not running (No in step S31), the disinfection determination unit 203 determines whether the door of the car 101 is closed (step S32). ). Then, when it is determined in step S32 that the door of the car 101 is not closed (No in step S32), there is a possibility that passengers will enter the car 101. Do not activate 105.

In step S32, when it is determined that the door of the car 101 is closed (Yes in step S32), the disinfection determination unit 203 measures the waiting time from closing the door (step S33), and the measured waiting time It is determined whether or not a predetermined time has elapsed (step S34).
When it is determined in step S34 that the standby time is equal to or longer than the predetermined time, the disinfection determination unit 203 sets the state of the disinfection unit 105 to "disinfecting" (step S35), and activates the disinfection unit 105 (step S36). ).

After activating the disinfection unit 105, the disinfection determination unit 203 determines whether or not the door of the car 101 is open (step S37). When it is determined in step S37 that the door of the car 101 is opened (Yes in step S37), the disinfection determination unit 203 stops the disinfection operation in the disinfection unit 105 (step S41).

Further, when it is determined in step S37 that the door of the car 101 is not open (No in step S37), the disinfection determination unit 203 determines the disinfection time after the disinfection unit 105 is activated in step S36. Measure (step S38). Then, the disinfection determining unit 203 determines whether or not the disinfection time measured in step S38 has passed the time necessary for disinfecting the push button 111 (step S39). The time required for disinfection of the push button 111 in step S39 is, for example, 30 seconds. The time required for disinfection, such as 30 seconds, is based on the time required for the disinfection unit 105 to disinfect the push button 111 by irradiating ultraviolet rays or the like, or the time required for the disinfectant applied by the disinfection unit 105 to evaporate and dry. is set.
In step S39, if the time required for disinfection of the push button 111 has not elapsed (No in step S39), the disinfection determination unit 203 returns to step S37 to determine whether the door is open.

When it is determined in step S39 that the time required for disinfecting the push button 111 has elapsed (Yes in step S39), the disinfection determination unit 203 sets the state of the disinfection unit 105 to "disinfected". (Step S40), the disinfecting operation of the disinfecting unit 105 is stopped in step S41.

[Failure judgment processing of non-contact button]
FIG. 7 is a flow chart showing an example of a process in which the abnormality determination unit 204 determines failure of the non-contact button 121 or a sign of failure.

First, the abnormality determination unit 204 confirms whether or not the push button 111 is operated (step S51). If the push button 111 has been operated (Yes in step S51), the abnormality determination unit 204 increments the value of the push button 111 operation count counter by one (step S52).
Further, the abnormality determination unit 204 confirms whether or not the non-contact button 121 is operated (step S53). If the non-contact button 121 is operated (Yes in step S53), the abnormality determination unit 204 increments the value of the operation counter of the non-contact button 121 by one (step S54).

If the push button 111 is not operated in step S51 (No in step S51) and if the non-contact button 121 is not operated in step S53 (No in step S53), the number of operations in step S52 or step S54 is determined. No incrementing of the counter value is performed.

FIG. 8 shows an example of an operation number counter.
In the case of the elevator device of this example, the operation number counter counts the number of times the push button 111 is operated and the number of times the non-contact button 121 is operated, divided into the days of the week and the time period of operation.
For example, the number of times the push button 111 is operated and the number of times the non-contact button 121 is operated are counted between 9:00 on Monday.

In this manner, the operation number counter counts the number of times the push button 111 is operated and the number of times the non-contact button 121 is operated every hour on each day of the week from Monday to Sunday. The count value of this operation number counter is stored in the control device 200, for example.
In the example of FIG. 8, the number of times the push button 111 is operated and the number of times the non-contact button 121 is operated are measured separately. You may measure the frequency|count of operation individually about every button of .

Returning to the explanation of the flowchart in FIG. It is determined whether or not it is smaller than the past average (step S55).
In this step S54, for example, the following comparison is performed.
[(non-contact button counter value) / (push button counter value + non-contact button counter value)] < [past average value x 80%]
The value of each counter here is the value for one hour of the corresponding time zone of the corresponding day of the week shown in FIG. The past average value is calculated, for example, by the following formula.
[past average value] = (past average of non-contact button counter) / [(past average of push button counter) + (past average of non-contact button counter)]
The past average of each counter for calculating the past average value is, for example, the average of the count values (the number of times the button is operated) for one hour in the corresponding time period in the past one month.

When the current value of [(non-contact button counter value)/(push button counter value + non-contact button counter value)] is smaller than 80% of the past average value in the comparison in step S55 (Yes in step S55), the abnormality determination unit 204 determines that there is a sign of failure of the non-contact button 121 (step S56). The sign of failure of non-contact button 121 determined in step S56 is reported from control device 200 to an external control center.

As shown in FIG. 8, the operation number counter measures the count value for each day of the week and each time slot, so that a sign of failure is determined for each day of the week and each time slot.
For example, at 14:00 on Monday, the utilization rate of the non-contact button 121 is calculated from the number of operations between 13:00 on Monday and compared with 80% of the average value of the number of operations between 13:00 on Monday. do. It should be noted that comparing the current utilization rate with the past average value of 80% at the time of comparison in step S55 is an example, and other percentage values may be used. Alternatively, current utilization may be directly compared to past averages without multiplying by a ratio such as 80 percent.

When it is determined in step S55 that it is not less than 80% of the past average (No in step S55), and after it is determined in step S56 that there is a sign, the abnormality determination unit 204 determines the number of operations in the past n hours. A comparison is made (step S57). Here, n hours refers to a time exceeding one hour, such as two hours.
That is, in step S57, the abnormality determination unit 204 determines that the number of times the push button 111 has been operated in the past n hours is smaller than the average value of the past number of times the push button 111 has been operated, and the number of times the non-contact button 121 has been operated is " 0” times or not.

In this step S57, when the number of times the push button 111 has been operated in the past n hours is smaller than the average value of the past number of times the push button 111 has been operated and the number of times the non-contact button 121 has been operated is "0" (step Yes in S57), the abnormality determination unit 204 determines that the non-contact button 121 is out of order (step S58). It should be noted that the failure of the non-contact button 121 is also reported from the control device 200 to the external control center in the same manner as when the sign is determined.

Further, after determining that the non-contact button 121 is out of order in step S58, the abnormality determination unit 204 causes the announcement unit 104 and the display unit 103 to output and display a voice saying, for example, "Non-contact button cannot be used." (step S59).
Further, when the abnormality determination unit 204 determines that the failure conditions calculated in step S57 are not satisfied (No in step S57), and after notifying that the non-contact button 121 cannot be used in step S59, the abnormality determination unit 204 determines whether or not the non-contact button 121 has been operated normally (step S60).

When it is determined in step S60 that the non-contact button 121 has been operated normally (Yes in step S60), the abnormality determination unit 204 causes the announcement unit 104 and the display unit 103 to generate a voice prompting the use of the non-contact button 121. is output and displayed (step S61).
In this step S61, the announcement unit 104 and the display unit 103 output and display a voice saying, for example, "Let's use the non-contact button."

When it is determined in step S60 that the non-contact button 121 has not been operated normally (No in step S60), and after outputting and displaying sound in step S61, the abnormality determination unit 204 The failure determination process shown in FIG. 7 ends.

As described above, according to the elevator system of this example, the car 101 has both the push button 111 and the non-contact button 121, and the non-contact floor registration using the non-contact button 121 and the push button 111 are performed. It is possible to register a stop floor by operating the push button used.
Therefore, in addition to the conventional push-button operation, non-contact operation that is highly effective in preventing infection such as viruses can be realized. In other words, it is possible to appropriately prevent infection with viruses or the like while ensuring the same operability as in the conventional system.
When the push button 111 is operated, the disinfection unit 105 is used to perform disinfection processing, so infection by a virus or the like due to the push button 111 can be effectively prevented.

In addition, when a situation arises in which disinfection by the disinfecting unit 105 is required, the announcement unit 104 and the display unit 103 notify the user to use the non-contact button, so the non-contact button is actively used. , the infection prevention effect can be increased.

In addition, since the disinfection by the disinfection unit 105 is performed while the inside of the car 101 is unmanned, the disinfection work can be safely performed. In addition, even if the disinfection work is in progress, the disinfection work is stopped when the door of the car 101 is opened. , the convenience of the elevator is not compromised.

[Modification]
It should be noted that the present invention is not limited to the above-described embodiments, and includes various modifications. For example, the above-described embodiment has been described in detail in order to explain the present invention in an easy-to-understand manner, and is not necessarily limited to those having all the described configurations.

For example, in the example shown in FIG. 1 , the first operating panel 110 and the second operating panel 120 in the car 101 are arranged separately on the left and right sides of the door 102 . On the other hand, the first operating panel 110 and the second operating panel 120 may be arranged adjacent to each other.

In addition, the first operation panel 110 is provided with a lid or a shutter that can be closed so as to hide the push buttons 111. When the push buttons 111 need to be disinfected, the lid or the like is closed and the push buttons 111 are closed. can be disabled. In addition, when the push button 111 is configured to be closed by providing a lid or the like, it becomes possible to operate the disinfection unit 105 with the lid closed, and the car 101 described in the flow chart of FIG. It becomes possible to perform disinfection outside of the situation.

Further, in the above-described embodiment, both the display by the display unit 103 and the sound output by the announcement unit 104 are performed as a notification to the user, but only one of them may be performed. In addition, as a notification to the user by display or sound, when performing disinfection, in addition to the notification such as "only non-contact buttons are valid", other push buttons and non-contact button operations such as "push buttons are invalid" You may make it notify about. Furthermore, even when not disinfecting, for example, a notification recommending the use of the non-contact button may always be sent.

In the processing shown in the flowchart of FIG. 5, when the push button 111 is operated and disinfection is required, the operation of the push button 111 is disabled. The stop floor may be registered using the push button 111 without invalidating the operation of the push button 111 . However, by disabling the operation of the push button 111 as in the processing shown in the flowchart of FIG. becomes higher.

Furthermore, in the block diagram of FIG. 2, only control lines and information lines that are considered necessary for explanation are shown, and not all control lines and information lines are necessarily shown on the product. In practice, it may be considered that almost all configurations are interconnected. Moreover, in the flowcharts shown in FIGS. 4 to 7, a plurality of processes may be executed simultaneously or the order of the processes may be changed as long as the processing results are not affected.

DESCRIPTION OF SYMBOLS 101... Car, 102... Door, 103... Display part, 104... Announcement part, 105... Disinfection part, 110... First operation panel, 111... Push button, 120... Second operation panel, 121... Non-contact button , 200... Control device, 201... Driving control unit, 202... Operation panel signal acquisition unit, 203... Disinfection determination unit, 204... Abnormality determination unit, 205... Communication unit, 211... Central processing unit (CPU), 212... ROM, 213... RAM, 214... non-volatile storage, 215... input interface, 216... output interface

Claims (5)

a first operation panel on which push buttons for registering a destination floor by user's touch operation are arranged;
a second operation panel on which a non-contact button for registering a destination floor by user's non-contact operation is arranged;
a control panel signal acquisition unit that acquires destination floor information from the first and second control panels;
a disinfection determination unit that instructs execution of disinfection when the operation panel signal acquisition unit detects the operation of the push button ;
a disinfection unit that disinfects the push button based on an instruction to perform disinfection by the disinfection determination unit;
and a notification unit that, when an instruction to perform disinfection by the disinfection unit is issued by the disinfection determination unit, provides guidance for prompting an operation of the non-contact button by voice or display. The elevator apparatus according to claim 1 , wherein, when the disinfection determining section instructs execution of disinfection, operation of the push button of the first operation panel is disabled until disinfection in the disinfection section is completed. The elevator apparatus according to claim 1 , wherein, when the disinfection determination unit instructs execution of disinfection, the disinfection unit executes disinfection when the car is unmanned and the door is closed. an abnormality determination unit that determines occurrence of failure or a sign of failure of the non-contact button based on information from the operation panel signal acquisition unit;
The elevator apparatus according to claim 1, further comprising a communication unit that notifies a control center based on the determination by the abnormality determination unit. The abnormality determination unit compares the ratio of the number of times the push button is operated and the number of times the non-contact button is operated in the most recent predetermined period with a past average value, and determines the non-contact 5. The elevator system according to claim 4 , wherein occurrence of failure or a sign of failure of the contact button is determined.

Images