CN114127000B

CN114127000B - Elevator system

Info

Publication number: CN114127000B
Application number: CN201980098520.1A
Authority: CN
Inventors: 大森阳太; 村上博行; 宫野一辉; 山﨑智史; 中谷彰宏; 上西一辉
Original assignee: Mitsubishi Electric Building Techno Service Co Ltd
Current assignee: Mitsubishi Electric Building Solutions Corp
Priority date: 2019-07-23
Filing date: 2019-07-23
Publication date: 2022-05-17
Anticipated expiration: 2039-07-23
Also published as: JPWO2021014572A1; WO2021014572A1; CN114127000A; JP6835263B1

Abstract

An elevator system (1) is provided with an imaging device (13), a control device (7A), a control device (7B), a detection unit (21), a detection unit (22), a determination unit (31), and an operation command unit (32). If the determination unit (31) determines that the isolation condition is established, the operation command unit (32) outputs a 1 st operation command to the control device (7A) and a 2 nd operation command to the control device (7B). The isolation condition is satisfied when the detection unit (21) detects that a 1 st user who is generating heat is present at a landing and the detection unit (22) detects that a 2 nd user other than the 1 st user is present at the landing.

Description

Elevator system

Technical Field

The present invention relates to an elevator system.

Background

Patent document 1 describes an elevator system. In the system described in patent document 1, the time at which the car arrives at the landing is adjusted in accordance with physical disabilities of the users. In addition, the opening time of the door is adjusted.

Documents of the prior art

Patent literature

Patent document 1: japanese patent laid-open publication No. 2015-224132

Disclosure of Invention

Problems to be solved by the invention

Elevators are utilized by various people. For example, a person who has a flu attack may use an elevator. In this case, the flu may be transmitted to other users who ride in the car together with the user. The system described in patent document 1 cannot solve such a problem.

The present invention has been made to solve the above problems. The invention aims to provide an elevator system capable of preventing infection of influenza and the like in a car.

Means for solving the problems

An elevator system of the present invention includes: an imaging device provided in a landing of an elevator; a 1 st control device for controlling a 1 st car stopped at a landing; a 2 nd control device for controlling the 2 nd car stopped at the landing; 1 st detection means for detecting that a 1 st user who is generating heat is present at a landing, based on an image captured by an imaging device; a 2 nd detection means for detecting that a 2 nd user other than the 1 st user is present at the landing, based on the image captured by the imaging device; a determination means that determines whether or not an isolation condition is satisfied when a call from a hall is registered; and an operation command unit that outputs a 1 st operation command for conveying the 1 st user to the 1 st control device and a 2 nd operation command for conveying the 2 nd user to the 2 nd control device when the determination unit determines that the isolation condition is satisfied. The isolation condition is satisfied when the 1 st detection means detects that the 1 st user is present at the landing and the 2 nd detection means detects that the 2 nd user is present at the landing.

An elevator system of the present invention includes: an imaging device provided in a landing of an elevator; a car that stops at a landing; a notifier provided at a landing; 1 st detection means for detecting that a 1 st user who is generating heat is present at a landing, based on an image captured by an imaging device; a 2 nd detection means for detecting that a 2 nd user other than the 1 st user is present at the landing, based on the image captured by the imaging device; a determination means that determines whether or not an isolation condition is satisfied when a call from a hall is registered; an operation control means for performing a 1 st operation for transporting a 1 st user by the car and a 2 nd operation for transporting a 2 nd user by the car when the determination means determines that the isolation condition is satisfied; and a notification control unit that causes the notifier to notify guidance for causing the 1 st user to board the car during the 1 st operation when the determination unit determines that the isolation condition is satisfied. The isolation condition is satisfied when the 1 st detection means detects that the 1 st user is present at the landing and the 2 nd detection means detects that the 2 nd user is present at the landing.

Effects of the invention

According to the present invention, infection of influenza and the like in the car can be prevented.

Drawings

Fig. 1 is a diagram showing an example of an elevator system according to embodiment 1.

Fig. 2 is a diagram showing an example of an elevator landing where a car stops.

Fig. 3 is a flowchart showing an example of the operation of the monitoring apparatus.

Fig. 4 is a flowchart showing an example of the operation of the group control device.

Fig. 5 is a flowchart showing an example of the operation of the control device receiving the 1 st operation command.

Fig. 6 is a diagram showing another example of the elevator system according to embodiment 1.

Fig. 7 is a flowchart showing an example of the operation of the control device.

Fig. 8 is a diagram showing an example of hardware resources of the monitoring apparatus.

Fig. 9 is a diagram showing another example of hardware resources of the monitoring apparatus.

Detailed Description

The invention is described with reference to the accompanying drawings. Duplicate descriptions are appropriately simplified or omitted. In the drawings, the same reference numerals denote the same or equivalent parts.

Embodiment mode 1

Fig. 1 is a diagram showing an example of an elevator system 1 according to embodiment 1. The elevator system 1 includes a monitoring device 2 and a group control device 3.

The group control device 3 controls a plurality of elevator devices 4 as one group. In the present embodiment, an example in which the elevator system 1 includes two elevator apparatuses 4 is shown as a simplest example. For example, as shown in fig. 1, the group control device 3 controls a machine a and a machine B. The machine A and the machine B are arranged in the same building. The group control device 3 may control 3 or more elevator devices 4.

Each elevator apparatus 4 includes a car 5, a drive device 6, and a control device 7. The car 5 moves up and down in the hoistway. The drive device 6 drives the car 5. The control device 7 controls the drive device 6. That is, the movement of the car 5 is controlled by the control device 7. The control device 7 controls devices provided in the car 5.

For example, the car 5 includes a door 8, a motor 9, a blower 10, and a bacteria removing device 11. The door 8 is driven by a motor 9. The blower 10 generates an airflow for taking air into the car 5. The bacteria removing device 11 is a device for removing bacteria from the inside of the car 5. For example, when the bacteria removing device 11 is operated, a chemical for removing bacteria is released into the car 5. The motor 9, the blower 10, and the sterilizing device 11 are controlled by the control device 7.

In the following description, when it is necessary to distinguish the elements provided in the elevator apparatus 4 by each machine, reference numerals a or B indicating the respective elements are given. For example, the machine a includes a car 5A, a drive device 6A, and a control device 7A. The car B includes a car 5B, a drive device 6B, and a control device 7B.

Fig. 2 is a diagram showing an example of a landing 12 of an elevator at which the car 5 stops. In the example shown in the present embodiment, both the car 5A and the car 5B are stopped at the landing 12. For example, the landing 12 shown in FIG. 2 is a landing on one floor of a building. The landing 12 is provided with an imaging device 13, an operation panel 14, and a notifier 15.

The imaging device 13 is, for example, a thermal imaging device. The image captured by the imaging device 13 includes temperature information. Information of the image captured by the imaging device 13 is input to the monitoring device 2. For example, the imaging device 13 is installed at a landing of all floors where the car 5 stops. The imaging device 13 may be installed at a landing on a part of the floor where the car 5 is parked.

The operation panel 14 is a device for a user to input a call registration request. For example, the operation panel 14 includes an up button and a down button. When the up button or the down button is pressed, a call registration request is output from the operation panel 14. A registration request from the operation panel 14 is input to the group control device 3. The operation panel 14 is provided at a landing of all floors where the car 5 stops.

The notifier 15 is a device for providing information to a user who is located at the landing 12. For example, the notifier 15 is a display. The annunciator 15 may also be a speaker. Both the display and the speaker may be provided as the annunciator 15 in the hall 12. For example, the annunciator 15 is provided at a landing of all floors where the car 5 stops. The annunciator 15 may be provided at a landing of a part of the floors at which the car 5 stops.

The monitoring device 2 includes an image analysis unit 20, a detection unit 21, a detection unit 22, and a signal output unit 23. The monitoring device 2 may have a function of communicating with the outside. For example, the monitoring apparatus 2 communicates with an external monitoring center via a specific network. The group control device 3 includes a call registration unit 30, a determination unit 31, an operation instruction unit 32, and a notification control unit 33. Hereinafter, the functions of the elevator system 1 will be described in detail with reference to fig. 3 to 5.

Fig. 3 is a flowchart showing an example of the operation of the monitoring apparatus 2. As described above, information of the image captured by the imaging device 13 is input to the monitoring device 2. The image captured by the imaging device 13 is analyzed by the image analysis unit 20 (S101). The method of analyzing the image by the image analyzer 20 may be any method as long as the detection can be performed by the detector 21 and the detector 22, which will be described later.

The detection unit 21 determines whether or not there is a user who generates heat at the landing 12 (S102). As an example, a user with a body temperature of 37.5 degrees or more is identified as a user who is fever. Hereinafter, the user who generates heat is also referred to as "1 st user". The detection unit 21 detects that the 1 st user is present at the landing 12 based on the image captured by the imaging device 13.

The detection unit 22 determines whether or not a user other than the 1 st user is present at the hall 12 (S103). Hereinafter, users other than the user who generates heat will also be referred to as "2 nd user". The detection unit 22 detects that the 2 nd user is present at the landing 12 based on the image captured by the imaging device 13.

The signal output unit 23 outputs a signal indicating the user status of the hall 12 to the group control device 3 based on the detection result of the detection unit 21 and the detection result of the detection unit 22. For example, if it is determined as yes in S103, the signal output unit 23 outputs the 1 st signal to the group management device 3 (S104). That is, when the detection section 21 detects that the 1 st user is present at the landing 12 and the detection section 22 detects that the 2 nd user is present at the landing 12, the signal output section 23 outputs the 1 st signal.

If it is determined as no in S103, the signal output unit 23 outputs the 2 nd signal to the group management device 3 (S105). That is, if the detection section 21 detects that the 1 st user is present at the landing 12 and the detection section 22 does not detect that the 2 nd user is present at the landing 12, the signal output section 23 outputs the 2 nd signal.

If it is determined as no in S102, the signal output unit 23 does not output a signal to the group control device 3. That is, if the detection section 21 does not detect that the 1 st user is present at the hall 12, the signal output section 23 does not output a signal to the group control device 3.

Fig. 4 is a flowchart showing an example of the operation of the group control device 3. In the group control device 3, when a registration request is input from the operation panel 14, the call registration section 30 registers a hall call (S201). When a call from a hall 12 is registered, the determination unit 31 determines whether or not an isolation condition for the hall 12 is established. The isolation condition is a condition set in advance for isolating the user who generates heat from other users. For example, the isolation condition is satisfied when the detection section 21 detects that the 1 st user is present at the landing 12 and the detection section 22 detects that the 2 nd user is present at the landing 12.

For example, when a call from the hall 12 is registered in S201, the determination unit 31 determines whether or not the 1 st signal is received from the monitoring device 2 (S202). The determination unit 31 determines that the isolation condition is satisfied if the 1 st signal is received from the monitoring device 2.

When the determination unit 31 determines that the isolation condition is satisfied, the operation instructing unit 32 outputs the 1 st operation instruction for conveying the 1 st user to the target floor to the control device 7A. When the determination unit 31 determines that the isolation condition is satisfied, the operation instructing unit 32 outputs a 2 nd operation instruction for transporting the 2 nd user to the target floor to the control device 7B (S203). The operation command unit 32 may output the 1 st operation command to the control device 7B based on the operation state of the machine a and the operation state of the machine B. In this case, the operation command unit 32 outputs the 2 nd operation command to the control device 7A.

When the determination unit 31 determines that the isolation condition is satisfied, the notification control unit 33 causes the notifier 15 to notify the 1 st user of guidance for boarding the car 5A (S204). This causes, for example, a display provided in the landing 12 to display "a person who is detecting heat generation. People with fever please use the machine A. "such a message. When the 1 st operation command is output to the control device 7B by the operation command section 32, the notification control section 33 notifies the notifier 15 of guidance for the 1 st user to get on the car 5B.

If the determination unit 31 determines no in S202, it determines whether or not the 2 nd signal is received from the monitoring device 2 (S205). Upon receiving the 2 nd signal from the monitoring device 2, the operation instructing unit 32 outputs a 1 st operation instruction for transporting the 1 st user to the destination floor to the control device 7A or the control device 7B (S206). In S206, the operation command unit 32 determines the output destination of the 1 st operation command based on the operation state of the machine a and the operation state of the machine B.

On the other hand, when the determination unit 31 determines "no" in S205, the operation instructing unit 32 outputs a 2 nd operation instruction for transporting the 2 nd user to the destination floor to the control device 7A or the control device 7B (S207). In S207, the operation command unit 32 determines the output destination of the 2 nd operation command based on the operation state of the machine a and the operation state of the machine B.

Fig. 5 is a flowchart showing an example of the operation of the control device 7 that receives the 1 st operation command. An example in which the control device 7A receives the 1 st operation command from the group control device 3 will be described below.

Upon receiving the 1 st operation command from the group control device 3, the control device 7A stops the unmanned car 5A at the landing 12, which is the boarding floor (S301). When the car 5A stops at the landing 12, the control device 7A opens and closes the door 8A (S302). Thus, the 1 st user who hears the notification of S204 gets on the car 5A, and inputs the destination floor in the car 5A.

When the destination floor is input, the control device 7A performs the direct travel operation from the boarding floor to the destination floor (S303). That is, the control device 7A does not cause the car 5A to respond to another hall call until the car 5A reaches the destination floor. After the car 5A stops at the target floor (S304), the control device 7A opens and closes the door 8A (S305). Thereby, the 1 st user gets off the car 5A.

After closing the door 8A at the destination floor, the control device 7A performs a sterilization operation for sterilizing the interior of the car 5A (S306). For example, the control device 7A operates the blower 10 in S306 to replace the air in the car 5A. As another example, the control device 7A operates the sterilizing device 11 in S306. When the sterilizing operation is completed, the control device 7A makes the car 5A respond to the newly registered call.

On the other hand, the control device 7B that has received the 2 nd operation command from the group control device 3 performs a normal operation in which the cars 5B sequentially respond to the registered calls. The user 2 located at the landing 12 rides on the car 5B and moves to the destination floor.

In the example shown in the present embodiment, if the isolation condition is established when a call from the hall 12 is registered, the car 5A stops at the hall 12 for the 1 st user, and the car 5B stops at the hall 12 for the 2 nd user. The 1 st user and the 2 nd user do not need to ride the same car 5 to move to the destination floor. Therefore, if the elevator system 1 shown in the present embodiment is used, infection of flu and the like in the car 5 can be prevented. The elevator system 1 according to the present embodiment is suitably applied to, for example, hospitals.

A part of the functions of the monitoring apparatus 2 may be provided in the group control apparatus 3. A part of the functions of the group control device 3 may be provided in the monitoring device 2. Further, another device may be installed in the hall 12, and this device may include a part of the functions of the monitoring devices 2 or a part of the functions of the group control devices 3.

In the present embodiment, an example in which the elevator system 1 includes a plurality of elevator devices 4 is described. This is but one example. An example in which the elevator system 1 includes 1 elevator apparatus 4 will be described below.

Fig. 6 is a diagram showing another example of the elevator system 1 according to embodiment 1. In the example shown in fig. 6, an elevator system 1 includes a monitoring device 2. Further, an imaging device 13, an operation panel 14, and a notification device 15 are provided in a landing 12 where the car 5 stops. Information of the image captured by the imaging device 13 is input to the monitoring device 2. The monitoring apparatus 2 performs the same operation as that shown in fig. 3. For example, in S104 and S105, the signal output unit 23 outputs a signal indicating the user status of the hall 12 to the control device 7.

In the example shown in fig. 6, the control device 7 has some of the functions of the group control device 3 in the example shown in fig. 1. A registration request from the operation panel 14 is input to the control device 7. The control device 7 includes a call registration unit 30, a determination unit 31, an operation control unit 34, and a notification control unit 33.

Fig. 7 is a flowchart showing an example of the operation of the control device 7. The processing shown in S401 and S402 in fig. 7 is the same as the processing shown in S201 and S202 in fig. 4. When a registration request is input from the operation panel 14, the call registration section 30 registers a hall call in the control device 7 (S401). When a call from a hall 12 is registered, the determination unit 31 determines whether or not an isolation condition for the hall 12 is established. As described above, the isolation condition is satisfied when the detection section 21 detects that the 1 st user is present at the landing 12 and the detection section 22 detects that the 2 nd user is present at the landing 12.

For example, when a call from the hall 12 is registered in S401, the determination unit 31 determines whether or not the 1 st signal is received from the monitoring device 2 (S402). The determination unit 31 determines that the isolation condition is satisfied if the 1 st signal is received from the monitoring device 2.

When the determination unit 31 determines that the isolation condition is satisfied, the operation control unit 34 sequentially performs the 1 st operation for transporting the 1 st user to the target floor and the 2 nd operation for transporting the 2 nd user to the target floor (S403). The operation control unit 34 may perform the 2 nd operation after the 1 st operation, or may perform the 1 st operation after the 2 nd operation. For example, the operation control unit 34 determines whether to perform the 1 st operation or the 2 nd operation first, based on the operation state when it is determined as "yes" in S402.

When the determination unit 31 determines that the isolation condition is satisfied, the notification control unit 33 notifies the notifier 15 of guidance for the 1 st user to get on the car 5 during the 1 st operation (S404). This causes, for example, a display provided in the hall 12 to display "a person who has detected heat generation. The heated person is preferentially directed to the target floor. Others please wait to ride the ladder. "such a message.

When the determination unit 31 determines no in S402, it determines whether or not the 2 nd signal is received from the monitoring device 2 (S405). Upon receiving the 2 nd signal from the monitoring device 2, the operation control unit 34 performs the 1 st operation for transporting the 1 st user to the destination floor (S406). On the other hand, when the determination unit 31 determines "no" in S405, the operation control unit 34 performs the 2 nd operation for transporting the 2 nd user to the destination floor (S407).

In the 1 st operation, the control device 7 operates in the same manner as in the example shown in fig. 5. For example, the operation control unit 34 performs a direct operation from the boarding floor to the destination floor in the 1 st operation. The operation control unit 34 performs a sterilization operation for sterilizing the inside of the car 5 after the door 8 is opened and closed at the target floor during the express operation.

In the present embodiment, reference numerals 20 to 23 denote functions of the monitoring device 2. Fig. 8 is a diagram showing an example of hardware resources of the monitoring apparatus 2. The monitoring apparatus 2 includes, as hardware resources, a processing circuit 40 including a processor 41 and a memory 42, for example. The memory 42 is, for example, a semiconductor memory. The memory 42 may not be a semiconductor memory. The monitoring device 2 realizes the functions of the respective parts shown by reference numerals 20 to 23 by the processor 41 executing the program stored in the memory 42.

Fig. 9 is a diagram showing another example of the hardware resources of the monitoring apparatus 2. In the example shown in fig. 9, the monitoring device 2 includes a processing circuit 40 including, for example, a processor 41, a memory 42, and dedicated hardware 43. Fig. 9 shows an example in which a part of the functions of the monitoring apparatus 2 is implemented by dedicated hardware 43. All the functions of the monitoring apparatus 2 may be realized by the dedicated hardware 43. As the dedicated hardware 43, a single circuit, a composite circuit, a programmed processor, a parallel programmed processor, an ASIC, an FPGA, or a combination thereof can be employed.

Similarly, in the example shown in fig. 1, reference numerals 30 to 33 denote functions of the group control device 3. The example of the hardware resources of the group control device 3 is the same as the example shown in fig. 8. For example, the group control device 3 includes a processing circuit including a processor and a memory as a hardware resource. The group control device 3 implements the functions of the respective units shown by reference numerals 30 to 33 by executing a program stored in a memory by a processor. The example of the hardware resources of the group control device 3 may be the same as the example shown in fig. 9. In this case, the group control device 3 includes a processing circuit including a processor, a memory, and dedicated hardware, for example. That is, a part of the functions of the group control device 3 may be realized by dedicated hardware. Further, all the functions of the monitoring apparatus 2 may be realized by dedicated hardware.

In the example shown in fig. 6,

reference numerals

30, 31, 33, and 34 denote functions of the control device 7. The example of the hardware resources of the control device 7 is the same as the example shown in fig. 8. For example, the control device 7 includes a processing circuit including a processor and a memory as a hardware resource. The control device 7 realizes the functions of the respective sections shown by

reference numerals

30, 31, 33, and 34 by executing programs stored in a memory by a processor. The example of the hardware resources of the control device 7 may be the same as the example shown in fig. 9. In this case, the control device 7 includes a processing circuit including, for example, a processor, a memory, and dedicated hardware. That is, a part of the functions of the control device 7 may be realized by dedicated hardware. Further, all the functions of the control device 7 may be realized by dedicated hardware.

Industrial applicability

The present invention can be applied to, for example, an elevator system in which an imaging device is installed in a hall.

Description of the reference symbols

1: an elevator system; 2: a monitoring device; 3: a group management device; 4: an elevator device; 5: a car; 6: a drive device; 7: a control device; 8: a door; 9: a motor; 10: a blower; 11: a bacteria removal device; 12: a landing; 13: a camera device; 14: an operation panel; 15: a notifier; 20: an image analysis unit; 21: a detection unit; 22: a detection unit; 23: a signal output section; 30: a call registration unit; 31: a determination unit; 32: an operation instruction unit; 33: a notification control unit; 34: an operation control unit; 40: a processing circuit; 41: a processor; 42: a memory; 43: dedicated hardware.

Claims

1. An elevator system, wherein the elevator system is provided with:

an imaging device provided at a landing of an elevator;

a 1 st control device that controls a 1 st car that stops at the landing;

a 2 nd control device that controls a 2 nd car that stops at the landing;

1 st detection means for detecting that a 1 st user who is generating heat is present at the hall, based on the image captured by the imaging device;

a 2 nd detection means for detecting that a 2 nd user other than the 1 st user is present at the hall, based on the image captured by the imaging device;

a determination means that determines whether or not an isolation condition is satisfied when a call from the hall is registered; and

an operation command unit that outputs a 1 st operation command for carrying the 1 st user to the 1 st control device and a 2 nd operation command for carrying the 2 nd user to the 2 nd control device when the determination unit determines that the isolation condition is satisfied,

the isolation condition is satisfied when the 1 st detecting means detects that the 1 st user is located at the landing and the 2 nd detecting means detects that the 2 nd user is located at the landing.

2. The elevator system according to claim 1, wherein the elevator system is further provided with:

a notifier provided at the landing; and

and a notification control unit that causes the notifier to notify guidance for the 1 st user to board the 1 st car when the determination unit determines that the isolation condition is satisfied.

3. The elevator system of claim 1 or 2, wherein,

when the 1 st operation command is input from the operation command means, the 1 st control device performs a direct operation from the landing to a destination floor.

4. The elevator system of claim 3,

the 1 st control device performs a sterilization operation for sterilizing the inside of the 1 st car after the door is opened and closed at the target floor during the express operation.

5. An elevator system, wherein the elevator system comprises:

an imaging device provided in a landing of an elevator;

a car that stops at the landing;

a notifier provided at the landing;

a determination means that determines whether or not an isolation condition is satisfied when a call from the hall is registered;

an operation control unit that performs a 1 st operation for transporting the 1 st user by the car and a 2 nd operation for transporting the 2 nd user by the car when the determination unit determines that the isolation condition is satisfied; and

a notification control means that causes the notifier to notify guidance for causing the 1 st user to ride on the car during the 1 st operation when the determination means determines that the isolation condition is satisfied,

6. The elevator system of claim 5,

the operation control means performs a direct operation from the landing to a destination floor in the 1 st operation.

7. The elevator system of claim 6,

the operation control means performs a sterilization operation for sterilizing the inside of the car after the door is opened and closed at the target floor during the express operation.