KR102427779B1 - Building including system for contolling robot-dedicated elevator and front area utilized as charging space and stnadby space for robot - Google Patents

Abstract

A control method and system for a robot-only elevator having an anterior chamber space are disclosed. For a robot-only elevator including at least one carrier on which a robot boards for vertical movement, and a front room, which is a space in which the robot waits before boarding the carrier, the carrier and the front room are separated based on the movement of the robot. A carrier door that separates and a front door that separates the front room and a corridor outside the front room are controlled.

Description

A building that includes a system for controlling an elevator dedicated to robots and an entire room used as a waiting space and charging space for robots

The description below relates to a technology for controlling an elevator for robot boarding.

An autonomous driving robot is a robot that finds an optimal route to a destination using wheels or legs while looking around and detecting obstacles by itself.

A robot used to provide a service in a building may have to board an elevator installed in the building to provide a service on a specific floor of the building. However, when the elevator is simply called and used by a robot or a robot control system that controls the robot, a crowded elevator is frequently called or the robot cannot board the elevator, which causes the robot to efficiently provide service. making it difficult to provide.

Accordingly, there is a need for a method and system for controlling an elevator for boarding of a robot, which can more efficiently provide a service by a robot.

Korean Patent Laid-Open No. 10-2005-0024840 is a technology related to a path planning method for an autonomous mobile robot, and it is a technology for a mobile robot that moves autonomously at home or in an office to avoid obstacles and to find an optimal path that can move safely and quickly to a target point. How to plan is disclosed.

The information described above is for understanding only, and may include content that does not form a part of the prior art, and may not include what the prior art can present to a person skilled in the art.

A method and system for controlling a robot-only elevator having an entire room that can be used as a waiting space and a charging space for a robot are provided.

A method and system for controlling the movement of a robot that organically moves the carrier, the front room, and the corridor outside the front room of the robot-only elevator are provided.

It provides a method and system to control the double door that separates the carrier and the front room, and the hallway outside the front room and the front room of the robot-only elevator according to the movement of the robot.

An elevator control method performed by a computer-implemented elevator control system, the elevator control system comprising at least one processor configured to execute computer readable instructions contained in a memory, the elevator control method comprising: To control a robot-dedicated elevator including at least one carrier on which the robot boards, and an entire room, which is a space in which the robot waits before boarding the carrier, by the at least one processor, the movement of the robot is controlled. Provided is an elevator control method comprising controlling a carrier door that separates the carrier from the front room based on the basis, and a front door that separates the front room and a corridor outside the front room.

According to an aspect, the controlling may include controlling one door of the carrier door and the front room door to open while the other door is closed.

According to another aspect, the controlling may include: directly controlling the opening and closing of the carrier door through the elevator control system; and controlling the opening and closing of the front door through a separate system interoperable with the elevator control system.

According to another aspect, as a node for controlling the movement line of the robot moving the carrier and the front room and the corridor, an external standby node waiting to enter the front room from outside the front room, to the carrier in the front room A layover node waiting to board the carrier, and an internal standby node waiting to advance from the front room to the hallway after getting off the carrier may be defined.

According to another aspect, the controlling may include: checking whether the carrier door is closed when a request to open the front door is received for the robot to enter or exit the front room; controlling the front door to be opened when the carrier door is in an open state and waiting for the carrier door is in a closed state; and controlling the front room door to close when the robot enters or exits the front room is completed.

According to another aspect, the controlling may include maintaining the closed state of the carrier door to open and close the front door, and maintain the closed state of the carrier door when the front door is closed after the robot enters or exits the front room It may further include the step of releasing.

According to another aspect, the controlling may include: checking whether the front door is closed when the carrier arrives on a current floor or a target floor of the robot; controlling the carrier door to be opened when the front door is in an open state and waiting for the front door to be opened; and controlling the carrier door to be closed when boarding or disembarking of the carrier of the robot is completed.

According to another aspect, the controlling may include maintaining the closed state of the front door to open and close the carrier door, and maintain the closed state of the front door when the carrier door is closed after the robot boards or disembarks the carrier. It may further include the step of releasing.

According to another aspect, the elevator control method may further include, by the at least one processor, controlling the movement of each robot by determining a boarding order in the front room according to the priority of the robot and other robots. can

According to another aspect, the elevator control method, by the at least one processor, detecting an elevator abnormality due to the entry of a person in the front room; And when the elevator abnormality is detected by the at least one processor, it may further include the step of converting the robot-only elevator to an unusable state.

It provides a non-transitory computer-readable recording medium in which a program for executing the elevator control method in a computer is recorded.

A computer-implemented elevator control system comprising: at least one processor configured to execute computer readable instructions contained in a memory; and at least one carrier on which a robot boards for vertical movement; Controls a dedicated robot elevator including a front room, a space in which the robot waits, and a carrier door that separates the carrier from the front room based on a movement line of the robot by the at least one processor, and the front room and the front room It provides an elevator control system, characterized in that it controls the front door that divides the hallway outside the front room.

According to embodiments of the present invention, it is a robot-only elevator having a front room that can be used as a waiting space and a charging space for the robot. have.

According to embodiments of the present invention, it is possible to organically control the double door that separates the robot carrier and the front room, and the corridor between the front room and the outside of the front room according to the movement of the robot, thereby promoting safety and efficiency in the use of the elevator.

1 shows an example of an elevator control environment for robot boarding, according to an embodiment.
2 is a block diagram illustrating a robot that provides a service in a building, according to an embodiment.
3 is a block diagram illustrating a system for controlling an elevator for robot boarding, according to an embodiment.
4 is a block diagram illustrating a robot control system for controlling a robot providing a service in a building, according to an embodiment.
Figure 5 shows an example of the structure of a robot dedicated elevator including an all-room space, according to an embodiment.
6 to 7 show examples of nodes referred to by the robot for movement in relation to the getting on and off of the elevator, according to an embodiment.
8 to 13 are flowcharts illustrating a method of controlling a robot-only elevator, according to an embodiment.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

These embodiments control a robot-only elevator equipped with an entire room space, and for safety and efficiency when a robot uses a robot-only elevator for vertical movement within a building, the carrier of the robot-only elevator, the front room, and the hallway outside the front room are organically You can control the movement of the moving robot.

1 shows an example of an elevator control environment for robot boarding, according to an embodiment.

1 illustrates elevators EV1 to EV8 installed in a building. The elevators EV1 to EV8 110 are devices that move between floors in a building, and may allow a user or the illustrated robot 100 to board and move between floors in a building. Each of the elevators 110 may be configured so that both a general user and the robot 100 can use it.

Each of the elevators 110 may be called and moved by the elevator control system 130 . For example, the elevator control system 130 may select an appropriate elevator according to a call from the user or the robot 100 (the robot control system 140 controlling the robot 100), and move the selected elevator to the called position. can do it The elevator control system 130 will be described in more detail with reference to FIG. 3 to be described later.

In the illustrated example, the elevator (EV8) 120 may be an elevator in which the robot 100 is called to board according to a call from the robot 100 (or the robot control system 140 that controls the robot). The elevator 120 is a dedicated elevator for boarding the robot 100 and may include an entire room. The structure of the robot-only elevator 120 will be described in more detail with reference to FIG. 5 to be described later.

The robot 100 may be a service robot used to provide services in a building. The robot 100 may be configured to provide a service on at least one floor. In addition, when there are a plurality of robots 100 , each of the plurality of robots may be configured to provide a service on at least one floor. In other words, according to the type/frequency of service and/or the shape/structure of the building (floor), the robot 100 may be configured to provide a service on one or more floors, and a plurality of robots may be installed on one floor. It may be configured to provide a service.

The service provided by the robot 100 may include, for example, at least one of a delivery service delivery service, a beverage (coffee, etc.) delivery service according to an order, a cleaning service, and other information/content providing services.

At least part of the movement of the robot 100 and the provision of services and calls to the robot dedicated elevator 120 may be made through the robot control system 140 . For example, according to a call by the robot control system 140 , the elevator control system 130 may move the robot-only elevator 120 to the floor where the robot 100 is located. The structure of the robot 100 and the robot control system 140 will be described in more detail with reference to FIGS. 2 and 4 to be described later.

The elevator control system 130 may detect that at least one robot 100 is boarded in the robot-only elevator 120, and operates the robot-only elevator 120 so that the robot 100 moves to the floor to which the service is to be provided. can be controlled

2 is a block diagram illustrating a robot that provides a service in a building, according to an embodiment.

As described above, the robot 100 may be a service robot used to provide services in a building. The robot 100 may provide a service to a user in a building at a predetermined location (a specific floor) of the building through autonomous driving.

The robot 100 may be a physical device, and as shown, may include a control unit 104 , a driving unit 108 , a sensor unit 106 , and a communication unit 102 .

The control unit 104 may be a physical processor built into the robot 100, and although not shown, a path planning processing module, a mapping processing module, a driving control module, a localization processing module, a data processing module, and a service processing module may include At this time, the path planning processing module, the mapping processing module, and the localization processing module are optional according to the embodiment in order to enable the indoor autonomous driving of the robot 100 even when communication with the robot control system 140 is not made. to be included in the control unit 104 .

The communication unit 102 may be configured for the robot 100 to communicate with other devices (such as another robot or robot control system 140 ). In other words, the communication unit 102 is a hardware module or network device, such as an antenna of the robot 100 , a data bus, a network interface card, a network interface chip and a networking interface port, etc., that transmits/receives data and/or information to/from other devices. It may be a software module such as a driver or a networking program.

The driving unit 108 controls the movement of the robot 100 and may include equipment for performing this as a configuration that enables movement.

The sensor unit 106 may be configured to collect data required for autonomous driving and service provision of the robot 100 . The sensor unit 106 may not include expensive sensing equipment, and may only include a sensor such as a low-cost ultrasonic sensor and/or a low-cost camera.

For example, the data processing module of the control unit 104 may transmit sensing data including output values of the sensors of the sensor unit 106 to the robot control system 140 through the communication unit 102 . The robot control system 140 may transmit route data generated using an indoor map in a building to the robot 100 . The path data may be transmitted to the data processing module through the communication unit 102 . The data processing module may directly transmit route data to the drive control module, and the drive control module may control the driving unit 108 according to the route data to control indoor autonomous driving of the robot 100 .

When the robot 100 and the robot control system 140 cannot communicate, the data processing module transmits the sensed data to the localization processing module, and generates path data through the path planning processing module and the mapping processing module to create the robot It is also possible to directly process the indoor autonomous driving of (100).

The robot 100 may be distinguished from a mapping robot used to generate an indoor map in a building. In this case, since the robot 100 does not include expensive sensing equipment, it is possible to process indoor autonomous driving by using an output value of a sensor such as a low-cost ultrasonic sensor and/or a low-cost camera. On the other hand, if the robot 100 has previously processed indoor autonomous driving through communication with the robot control system 140 , the mapping data included in the route data previously received from the robot control system 140 is further added. By using it, more accurate indoor autonomous driving may be possible while using low-cost sensors.

The service processing module may receive a command received through the robot control system 140 through the communication unit 102 or through the communication unit 102 and the data processing module. The driving unit 108 may further include equipment related to a service provided by the robot 100 as well as equipment for moving the robot 100 . For example, in order to perform a food/delivery delivery service, the driving unit 108 of the robot 100 is configured to load food/delivery or deliver food/delivery to a user (eg, robot arm). may include In addition, the robot 100 may further include a speaker and/or a display for providing information/content. The service processing module may transmit a driving command for the service to be provided to the driving control module, and the driving control module may control the configuration included in the robot 100 or the driving unit 108 according to the driving command to provide the service. can make it

The robot 100 may board the robot-only elevator 120 called through control by the robot control system 140 . When the robot-only elevator 120 arrives at a floor for the robot 100 to provide a service, the robot 100 can get off the robot-only elevator 120 and provide a service on the corresponding floor.

The description of the technical features described above with reference to FIG. 1 may be applied to FIG. 2 as it is, and thus a redundant description will be omitted.

3 is a block diagram illustrating a system for controlling an elevator for robot boarding, according to an embodiment.

The elevator control system 130 may be a device for controlling the movement of the elevators 110 and a call to the elevators 110 in the above-described building. The elevator control system 130 may include at least one computing device, and may be implemented as a server located inside or outside the building.

As shown, the elevator control system 130 may include a memory 330 , a processor 320 , a communication unit 310 , and an input/output interface 340 .

The memory 330 is a computer-readable recording medium and may include a random access memory (RAM), a read only memory (ROM), and a permanent mass storage device such as a disk drive. Here, the ROM and the non-volatile mass storage device may be separated from the memory 330 and included as separate permanent storage devices. Also, an operating system and at least one program code may be stored in the memory 330 . These software components may be loaded from a computer-readable recording medium separate from the memory 330 . The separate computer-readable recording medium may include a computer-readable recording medium such as a floppy drive, a disk, a tape, a DVD/CD-ROM drive, and a memory card. In another embodiment, the software components may be loaded into the memory 330 through the communication unit 310 rather than a computer-readable recording medium.

The processor 320 may be configured to process instructions of a computer program by performing basic arithmetic, logic, and input/output operations. The command may be provided to the processor 320 by the memory 330 or the communication unit 310 . For example, the processor 320 may be configured to execute a received instruction according to a program code loaded into the memory 330 . Such a processor 320 may include an elevator control unit 322, and an abnormality detection unit 324, as shown.

Each of the components 322 to 324 of the processor 320 may be a software and/or hardware module as part of the processor 320 , and may represent a function (functional block) implemented by the processor.

The elevator control unit 322 may control the robot-only elevator 120 so that the robot-only elevator 120 moves to the current floor of the robot 100 or a floor to which the robot 100 will provide a service. In particular, as the elevator control unit 322 has the control right for opening and closing the door of the robot-only elevator 120 in the elevator control system 130, the door of the robot-only elevator 120 is opened according to the movement line of the robot when boarding or getting off the robot. and closing can be controlled. In this embodiment, the robot-only elevator 120 includes the front room space, and in this case, the door of the robot-only elevator 120 separates the robot carrier and the front room, which are the boarding spaces of the robot 100, and the front room and the hallway outside the front room. It may consist of a double door for The elevator control unit 322 may control the movement of the robot 100 and the opening and closing of the door so that the carrier door that separates the robot carrier and the front room and the front door that separates the front room and the hallway outside the front room do not open at the same time. The carrier door and the front door may be electrically connected to each other so that only one of them is opened without being opened at the same time. In addition, the carrier door and the front door may be managed by a separate system. The carrier door may be managed by the elevator control system 130 , and the front door may be managed by the gate control system 150 configured as a security system capable of interworking with the elevator control system 130 . The gate control system 150 may control opening and closing of the front door based on communication with the elevator control system 130 . The gate control system 150 may also include at least one computing device like the elevator control system 130 , and may be implemented as a security system included in a building.

The abnormality detection unit 324 may detect an elevator abnormality due to the entry of a robot carrier or a person in the front room using a CCTV camera or a motion detection sensor installed in the robot elevator 120 . The elevator control unit 322 may switch to an emergency state for the robot-only elevator 120 when an elevator abnormality is detected by the abnormality detection unit 324 and stop the elevator operation, and furthermore, through an emergency light notification or announcement, etc. It can induce people to leave.

The communication unit 310 may be configured for the elevator control system 130 to communicate with other devices (elevators 110 or robot control system 140, gate control system 150, etc.). In other words, the communication unit 310 transmits/receives data and/or information to other devices, such as an antenna of the elevator control system 130, a data bus, a network interface card, a network interface chip and a hardware module such as a networking interface port, or It may be a software module such as a network device driver or a networking program.

The input/output interface 340 may be a means for interfacing with an input device such as a keyboard or mouse and an output device such as a display or speaker.

Also, in other embodiments, the elevator control system 130 may include more components than the illustrated components.

A method of controlling the robot elevator 120 for boarding the robot 100 performed by the components 322 to 324 of the processor 320 will be described in more detail with reference to FIGS. 5 to 13 to be described later. .

The description of the technical features described above with reference to FIGS. 1 and 2 can be applied to FIG. 3 as it is, and thus a redundant description will be omitted.

4 is a block diagram illustrating a robot control system for controlling a robot providing a service in a building, according to an embodiment.

The robot control system 140 may be a device that controls the movement of the robot 100 and the provision of services in a building by the robot 100 . The robot control system 140 may control movement of each of the plurality of robots and provision of services of each of the robots. The robot control system 140 may call the elevator to move the robot 100 to a floor where the robot 100 will provide a service through communication with the elevator control system 130 . The robot control system 140 controls the robot 100 so that the robot 100 can recognize the called robot elevator 120 and get on, and to get off the robot elevator 120 at the floor where the service is to be provided. The robot 100 can be controlled.

The robot control system 140 may include at least one computing device, and may be implemented as a server located inside or outside the building. The robot control system 140 may be implemented as a cloud server (system).

As illustrated, the robot control system 140 may include a memory 430 , a processor 420 , a communication unit 410 , and an input/output interface 440 . For the general description of the components 410 to 430 of the robot control system 140, the description of the general technical characteristics of the components 310 to 340 of the elevator control system 130 described above can be applied as it is, so the overlapping A description is omitted.

The description of the technical features described above with reference to FIGS. 1 to 3 can be applied to FIG. 4 as it is, and thus a redundant description will be omitted.

Figure 5 shows an example of the structure of a robot dedicated elevator including an all-room space, according to an embodiment.

Referring to FIG. 5 , the robot elevator 120 corresponds to a robot transport device for vertical movement of the robot 100 , and may include an anterior chamber space 503 . The front room 503 represents a space waiting for the robot 100 to get on and off, and may be used as a space for charging the robot 100 according to an embodiment.

As an example, the robot-only elevator 120 is a space in which the robot 100 is boarded when the robot 100 moves vertically, that is, an upward carrier 501 for vertical upward movement of the robot carrier and a descending carrier for vertical downward movement ( 502) may be configured.

The robot-only elevator 120 has a double door structure to prevent human entry, and includes carrier doors 510-1 and 510-2 and the front room 503 that separate the robot carriers 501 and 502 from the front room 503. It may include an anterior chamber door 520 that divides the corridor outside the anterior chamber.

The front door 520 is an entrance area in which the left section enters the front room space 503 from the central position of the front room door 520 based on the front room door 520 viewed from the outside, and the right section enters the front room space 503 from the outside. It can be used by dividing the exit area.

The front door 520 shown as an example in FIG. 5 has a structure in which the entrance and the exit are shared, but is not limited thereto. The other can also be used as an exit.

The carrier doors 510-1 and 510-2 and the front door 520 may be configured in a double-door structure that opens in both left and right directions, and according to an embodiment, the carrier doors 510-1 and 510-2 may be formed in either the upper, lower, left, or right. While having a structure that opens to either side, the front door 520 may have a double-door structure.

The robot-only elevator 120 has an anterior chamber space 503 that can use both the ascending carrier 501 and the descending carrier 502, and the elevator control system 130 for controlling the robot-only elevator 120 is a robot. By organically controlling the robot getting off the carrier (501, 502) and the robot boarding the robot carrier (501, 502), it is possible to efficiently operate the robot getting on and off.

The carrier doors 510-1 and 510-2 can be opened and closed at the same time. The robots may simultaneously board or disembark the ascending carrier 501 and the descending carrier 502 . When one robot gets off the robot carriers 501 and 502 , the other waiting robot can get on the robot carriers 501 and 502 . When the carrier doors 510-1 and 510-2 are opened, the robot in a boarding state alights from the robot carriers 501 and 502 and moves to the front room space 503, and the waiting robot moves in the front room space 503 to move the robot carrier. You can ride on (501, 502).

The elevator control system 130 controls the movement of the robot and the opening and closing of the door so that the carrier doors 510-1 and 510-2 and the front door 520 do not open at the same time in order to minimize the noise generation due to safety issues and the stack phenomenon. can After checking the closed state of one of the carrier doors 510-1 and 510-2 and the front door 520, the open state of the other door is determined. That is, when one door is open, the other door is Wait for a moment to open.

6 illustrates an example of a node referenced by the robot for movement in relation to the getting on and off of the elevator, according to an embodiment.

A node referenced for movement of the robot 100 is defined in order to control the movement of the robot 100 organically moving through the robot carriers 501 and 502, the front room 503, and the corridor outside the front room 503. can be

Referring to FIG. 6 , an outside waiting node (waiting_outside node) 601 is defined as a point waiting to pass through the front room door 520 from the outside to the inside of the front room space 503 . The external standby node 601 may be assigned to at least one side with respect to the front door 520 in front of the robot dedicated elevator 120 . The external standby node 601 shown as an example in FIG. 6 is designated at the left side of the front door 520 viewed from the outside, but is not limited thereto. At least one or more such as the left, right, and center of the front door 520 Points can be assigned.

A layover node 602 is defined as a point at which the robot carriers 501 and 502 wait before boarding in the anterior chamber space 503 . The layover node 602 may be assigned at least one or more points in consideration of the number of robots capable of waiting simultaneously in the front room space 503 or the movement between robots getting on and off the robot carriers 501 and 502 in the front room space 503. have. The layover node 602 may be divided into a waiting point for boarding of the uplink carrier 501 and a waiting point for boarding of the downlink carrier 502 . The layover node 602 illustrated by way of example in FIG. 6 is designated at the inner center of the anterior chamber space 503, but is not limited thereto. As shown in FIG. 7 , a layover node 602 is designated at at least one point inside the front room space 503 according to the area or structure of the front room space 503 and the structure or location of the front room door 520 . can be

Referring back to FIG. 6 , an ascending boarding waiting node (waiting_up node) 603 is defined as a point waiting to pass through an ascending carrier door 510-1 before boarding an ascending carrier 501, and a descending boarding waiting node (waiting_down node) 604 is defined as a point waiting to pass through the downlink carrier door 510 - 2 before boarding the downlink carrier 502 . The ascending boarding standby node 603 and the descending boarding waiting node 604 may be assigned to at least one side with respect to the carrier doors 510-1 and 510-2. The ascending boarding waiting node 603 and the descending boarding waiting node 604 shown by way of example in FIG. 6 are designated at the central side points of the carrier doors 510-1 and 510-2, but are not limited thereto, and the carrier It may be assigned to at least one or more points, such as the left, right, and center of the doors 510-1 and 510-2.

An inside waiting node (waiting_door node) 605 is defined as a point waiting to pass through the front room door 520 from the inside of the front room space 503 to the outside. The internal standby node 605 is a point at which the robot, disembarked from the robot carriers 501 and 502, waits to exit the front room space 503, and may be designated on at least one side with respect to the front room door 520. The internal standby node 605 may be assigned to the side of the front door 520 that is basically used as an exit, and the robot waiting on the external standby node 605, or the ascending carrier 501 and the descending carrier 502. It may be designated on both sides of the front door 520 in consideration of the simultaneous alighting robot and the like.

The robot control system 140 uses the above-described nodes 601 to 605 to organically move the robot carriers 501 and 502, the front room 503, and the corridor outside the front room 503. can control the movement of

(1) Waiting for use of the robot-only elevator 120

In order for the robot 100 to use the robot elevator 120, the robot 100 moves to an external standby node 601, which is a starting point of a waypoint, and waits.

(2) Entrance to the front room (503)

When the front door 520 of the robot elevator 120 is opened, the robot 100 moves into the front room space 503 . When the robot 100 reaches the entry completion point in the front room space 503 , the front room door 520 is closed.

(3) Wait for layover station

The robot 100 entering the front room space 503 moves to a layover station corresponding to the layover node 602 and waits. The layover station corresponds to a place where the robot 100 waits for the robot carriers 501 and 502 to be boarded.

(4) Boarding the ascending carrier (501)

In order to move from the current floor to the upper floor, the ascending carrier 501 is used. After the ascending carrier 501 arrives at the current floor, when the robot 100 moves from the layover node 602 to the ascending boarding standby node 603 , the ascending carrier door 510-1 is opened. The robot 100 moves into the ascending carrier 501 when the ascending carrier door 510-1 is opened. When the robot 100 reaches the boarding completion point in the ascending carrier 501 , the ascending carrier door 510-1 is closed.

(5) Boarding the downbound carrier 502

In order to move from the current floor to the lower floor, the downlink carrier 502 is used. After the downbound carrier 501 arrives at the current floor, when the robot 100 moves from the layover node 602 to the downbound boarding waiting node 604 , the downlink carrier door 510 - 2 is opened. The robot 100 moves into the descending carrier 502 when the descending carrier door 510 - 2 is opened. When the robot 100 reaches the boarding completion point in the descending carrier 502 , the descending carrier door 510 - 2 is closed.

(6) Get off the downbound carrier 502

The robot 100 moving from the upper floor to the current floor gets off the descending carrier 502 when the descending carrier door 510 - 2 is opened. When the robot 100 exits the descending carrier 502 and arrives at the descending boarding standby node 604 , the descending carrier door 510-2 is closed, and at this time, the robot 100 enters the interior standby node to exit the front room 503. Go to (605) and wait. The robot 100, which got off the descending carrier 502, moves to the internal waiting node 605 on the side of the front door 520, which is basically used as an exit, and in some cases (for example, the case, etc.) moves to the internal standby node 605 close to the downlink carrier 502 . When there is no other robot waiting in the external standby node 601 in an environment where movement of the shortest path is prioritized, the robot 100 that got off the descending carrier 502 is used as the entrance to the internal standby node on the front door 520 side. Moving to 605 is also possible.

(7) Get off the ascending carrier 501

The robot 100 moving from the lower floor to the current floor gets off the upper carrier 501 when the upper carrier door 510-1 is opened. When the robot 100 comes out of the ascending carrier 501 and arrives at the ascending boarding standby node 603 , the ascending carrier door 510-1 is closed, and at this time, the robot 100 is an internal standby node in order to exit the anterior chamber space 503. Go to (605) and wait. The robot 100, which got off the ascending carrier 501, moves to the internal standby node 605 on the side of the front door 520, which is basically used as an exit, and in some cases (for example, the case, etc.) moves to an internal standby node 605 close to the uplink carrier 501 . When there is no other robot waiting at the external standby node 601 in an environment where movement of the shortest path is prioritized, the robot 100 disembarked from the ascending carrier 501 is used as the entrance to the internal standby node on the front door 520 side. Moving to 605 is also possible.

(8) Advance to the front room space (503)

The robot 100 waiting in the internal standby node 605 moves out of the front room space 503 when the front room door 520 of the robot elevator 120 is opened. When the robot 100 reaches the entry completion point of the front room space 503 , the front room door 520 is closed.

It is also possible to control the simultaneous movement by a plurality of robots in addition to the above-described movement lines. For example, the robot control system 140 includes the movement of two robots simultaneously entering the anterior chamber space 503 , the movement of two robots simultaneously advancing from the anterior chamber space 503 , and the robot riding on the descending carrier 502 and ascending. The movement of the robot getting off the carrier 501, the movement of the robot getting on the ascending carrier 501 and the robot getting off the descending carrier 502, the robot entering the anterior chamber space 503, and the robot entering the anterior chamber space 503 The movement line of the robot that moves, the movement of the robot riding on the ascending carrier 501 and the robot riding on the descending carrier 502, the movement of the robot getting off the ascending carrier 501 and the robot getting off the descending carrier 502, the upward movement Two robots disembarking from the carrier 501 and the descending carrier 502 at the same time and the robot waiting in the anterior chamber space 503, two robots disembarking simultaneously from the ascending carrier 501 and the descending carrier 502, and the anterior chamber space It is possible to control the movement lines of the two robots that are waiting inside and outside the 503, respectively.

In addition, the robot control system 140 may change the movement line of each robot by resetting the boarding order of the robots in the front room 503 according to the priority of each robot. For example, if robot A that needs urgent movement is assigned an elevator in which robot B is currently moving vertically, robot B stops at the floor where robot A is waiting, gets off in the front room 503, and waits for the next elevator. Robot A rides the elevator that robot B has taken.

8 to 13 are flowcharts illustrating a method of controlling a robot-only elevator, according to an embodiment.

In the detailed description to be described later, the operation performed by the components of the robot 100 , the elevator control system 130 , the robot control system 140 , or the gate control system 150 is the robot 100 , the elevator for convenience of description. It may be described as an operation performed by the control system 130 , the robot control system 140 , or the gate control system 150 .

First, a process of entering the front room will be described with reference to FIG. 8 .

Referring to FIG. 8 , the robot 100 is an external waiting node 601 in front of the front door 520 of the robot-only elevator 120 under the control of the robot control system 140 to use the robot-only elevator 120 . wait in (S801). The robot control system 140 checks whether there is another robot waiting in the layover node 602 in the front room space 503 (S802). The robot control system 140 controls to maintain the standby state in the external standby node 601 of the robot 100 when there is another robot waiting in the layover node 602, and waits in the layover node 602 If there is no other robot in operation, a request to open the front door 520 is transmitted to the elevator control system 130 (S803). The elevator control system 130 checks the closed state of all the carrier doors 510 - 1 and 510 - 2 in order to check whether it is possible to enter the front space 503 according to the request to open the front door 520 ( S804 ). ). The elevator control system 130 waits when any one of the carrier doors 510-1 and 510-2 is open, and when all of the carrier doors 510-1 and 510-2 are closed, the It is determined that the entry is possible, and a request to open the front door 520 is transmitted to the gate control system 150 (S805). At this time, the elevator control system 130 transmits the request to open the front door 520 to the gate control system 150 and controls the carrier doors 510-1 and 510-2 to maintain the closed state. The gate control system 150 transmits a command to open the front door 520 to the elevator 120 (S806), and the elevator 120 opens the front door 520 according to the command of the gate control system 150 (S807) An open state of the front door 520 may be displayed. The gate control system 150 checks the open state of the front door 520 ( S808 ) and simultaneously transmits the open state information of the front door 520 to the robot control system 140 . The gate control system 150 transmits the open state information of the front door 520 directly to the robot control system 140 as well as through the elevator control system 130 . The robot control system 140 confirms the open state of the front room door 520 and simultaneously transmits a movement command to the front room space 503 to the robot 100 (S809). The robot 100 moves into the anterior chamber space 503 of the elevator 120 according to the movement command of the robot control system 140 (S810) and waits at the layover node 602 in the anterior chamber space 503 (S811) . When the robot 100 reaches the entry completion point in the front room space 503, the robot control system 140 confirms the entry completion status of the robot 100 and then sends a request to close the front door 520 to the elevator control system 130 ) to (S812). The elevator control system 130 transmits a request to close the front door 520 to the gate control system 150 (S813), and the gate control system 150 sends the elevator 120 a command to close the front door 520 (S813). is transmitted (S814). The elevator 120 closes the front door 520 according to the command of the gate control system 150 (S815), and the gate control system 150 checks the closed state of the front door 520 (S816) It transmits the closing state information of the 520 to the elevator control system 130 . When the closed state of the front door 520 is confirmed, the elevator control system 130 releases the maintenance of the closed state of the carrier doors 510-1 and 510-2 (S817).

Next, a carrier boarding process will be described with reference to FIGS. 9 and 10 .

Hereinafter, the boarding process of the robot carrier corresponding to the ascending carrier 501 will be described, but the boarding process of the descending carrier 502 is also the same.

Referring to FIG. 9 , when the robot carrier 501 arrives at the scheduled boarding floor of the robot 100 ( S901 ), the elevator control system 130 transmits the arrival status information of the robot carrier 501 to the robot control system 140 . It transmits (S902). The elevator control system 130 requests the state of the front door 520 to the gate control system 150 when the robot carrier 501 arrives at the boarding floor of the robot 100 (S903). The gate control system 150 checks the status of the front door 520 according to the request of the elevator control system 130 and then transmits the corresponding status information to the elevator control system 130 (S904). The elevator control system 130 checks whether the front door 520 is currently closed (S905). If the front room door 520 is not closed, it waits until the closing state information is received from the gate control system 150, and if the front room door 520 is currently closed, the door of the robot carrier 501 to the elevator 120 That is, a command to open the carrier door 510-1 is transmitted (S906). When the elevator 120 opens the carrier door 510-1 (S907), the elevator control system 130 checks the open state of the carrier door 510-1 and then transmits it to the robot control system 140 (S908) . Meanwhile, when the arrival status of the robot carrier 501 is confirmed, the robot control system 140 prepares to board the robot 100 ( S909 ), and checks whether there is another robot to get off the robot carrier 501 . (S910). When there is another robot to get off the robot carrier 501, the robot control system 140 transmits a move command to the internal standby node 605 along with a disembarkation command from the robot carrier 501 to the other robot (S911). ). Accordingly, after the robot gets off the robot carrier 501 according to the command of the robot control system 140 , it moves to the internal standby node 605 of the front room 503 and waits ( S912 ). When there is no other robot to get off the robot carrier 501 or the disembarkation of another robot is confirmed (S913), the robot control system 140 boards the robot 100 waiting for boarding in the layover node 602. A move command to the standby node 603 is transmitted (S914).

Referring to FIG. 10 , when the robot 100 moves to the boarding standby node 603 ( S1015 ) and the open state of the carrier door 510-1 is confirmed, the robot control system 140 sends the robot 100 to board the carrier. A command is transmitted (S1016). When the robot 100 boards the robot carrier 501 according to the carrier boarding command of the robot control system 140 (S1017) and the robot 100 reaches the boarding completion point in the robot carrier 501, the robot control system 140 ) transmits a request to close the carrier door 510-1 to the elevator control system 130 after confirming the boarding completion state of the robot 100 (S1018). The elevator control system 130 transmits a closing command of the carrier door 510-1 to the elevator 120 (S1019), and the elevator 120 closes the carrier door 510-1 to this (S1020) robot ( 100) moves the robot carrier 501 to the target floor (S1021).

Next, a carrier unloading process will be described with reference to FIG. 11 .

Hereinafter, the unloading process of the robot carrier corresponding to the ascending carrier 501 will be described, but the unloading process of the descending carrier 502 is also the same.

Referring to FIG. 11 , when the robot carrier 501 arrives at the destination floor of the robot 100 ( S1101 ), the elevator control system 130 transmits the arrival status information of the robot carrier 501 to the robot control system 140 . do (S1102). When the robot carrier 501 arrives at the target floor of the robot 100, the elevator control system 130 requests the gate control system 150 for the state of the front door 520 (S1103). The gate control system 150 checks the state of the front door 520 according to the request of the elevator control system 130 and then transmits the corresponding state information to the elevator control system 130 (S1104). The elevator control system 130 checks whether the front door 520 is currently closed (S1105). If the front room door 520 is not closed, it waits until the closing state information is received from the gate control system 150, and if the front room door 520 is currently closed, the door of the robot carrier 501 to the elevator 120 That is, a command to open the carrier door 510-1 is transmitted (S1106). When the elevator 120 opens the carrier door 510-1 (S1107), the elevator control system 130 checks the open state of the carrier door 510-1 and then transmits it to the robot control system 140 (S1108) . The robot control system 140 prepares for unloading of the robot 100 when the arrival state of the robot carrier 501 is confirmed (S1109), and when the open state of the carrier door 510-1 is confirmed, the robot 100 It transmits a move command to the internal standby node 605 together with a get-off command from the robot carrier 501 to the target (S1110). Accordingly, the robot 100 gets off the robot carrier 501 according to the command of the robot control system 140 , and then moves to the internal standby node 605 of the front room 503 and waits ( S1111 ). The robot control system 140 transmits a request to close the carrier door 510-1 to the elevator control system 130 after confirming the disembarkation completion status of the robot 100 when the robot 100 gets off the robot carrier 501. do (S1112). The elevator control system 130 transmits a closing command of the carrier door 510-1 to the elevator 120 (S1113), whereby the elevator 120 closes the carrier door 510-1 (S1114).

Similarly, when the robot 100 boards the robot carrier 501 or gets off the robot carrier 501, it controls so that the closed state of the front door 520 is maintained for opening and closing the carrier door 510-1, When the loading and unloading of the robot 100 is completed and the closed state of the carrier door 510-1 is confirmed, the maintenance of the closed state of the front door 520 is released.

Next, a process of advancing to the front room will be described with reference to FIG. 12 .

Referring to FIG. 12 , after the robot 100 gets off the robot carrier 501 and moves to the internal standby node 605 of the front room space 503, when the carrier door 510-1 is closed, the robot control system 140 transmits the request to open the front door 520 to the elevator control system 130 (S1201). The elevator control system 130 checks the closed state of all the carrier doors 510 - 1 and 510 - 2 according to the request to open the front door 520 ( S1202 ). The elevator control system 130 waits when any one of the carrier doors 510-1 and 510-2 is open, and the gate control system 150 when the carrier doors 510-1 and 510-2 are all closed. to transmit the request to open the front door 520 (S1203). At this time, the elevator control system 130 transmits the request to open the front door 520 to the gate control system 150 and controls the carrier doors 510-1 and 510-2 to maintain the closed state. The gate control system 150 transmits a command to open the front door 520 to the elevator 120 (S1204), and the elevator 120 opens the front door 520 according to the command of the gate control system 150 (S1205) An open state of the front door 520 may be displayed. The gate control system 150 checks the open state of the front door 520 ( S1206 ) and simultaneously transmits the open state information of the front door 520 to the robot control system 140 . The gate control system 150 transmits the open state information of the front door 520 directly to the robot control system 140 as well as through the elevator control system 130 . The robot control system 140 confirms the open state of the front room door 520 and transmits a movement command to advance from the front room space 503 to the robot 100 at the same time (S1207). The robot 100 moves out of the front room 503 of the elevator 120 according to the movement command of the robot control system 140 (S1208). When the robot 100 reaches the exit completion point outside the front room space 503, the robot control system 140 checks the completion status of the robot 100 advances to the front room and then sends a request to close the front door 520 to the elevator control system 130 ) to (S1209). The elevator control system 130 transmits a request to close the front door 520 to the gate control system 150 (S1210), and the gate control system 150 sends the elevator 120 a command to close the front door 520 (S1210). is transmitted (S1211). The elevator 120 closes the front door 520 according to the command of the gate control system 150 (S1212), and the gate control system 150 checks the closing state of the front door 520 (S1213) It transmits the closing state information of the 520 to the elevator control system 130 . When the closed state of the front door 520 is confirmed, the elevator control system 130 releases the maintenance of the closed state of the carrier doors 510-1 and 510-2 (S1214).

Next, an abnormality detection process will be described with reference to FIG. 13 .

Referring to FIG. 13 , the elevator 120 detects abnormality in the elevator due to the entry of a person in the front room 503 using a CCTV camera or a motion sensor ( S1301 ). When the gate control system 150 detects an abnormality in the elevator 120, the gate control system 150 switches the current floor where the abnormality is detected to an emergency state (S1302). The gate control system 150 transmits emergency state information according to the elevator abnormality to the robot control system 140 , and the robot control system 140 converts the elevator to an elevator unavailable state of the robot 100 ( S1303 ). In addition, the gate control system 150 may notify the emergency state information according to the elevator abnormality to the disaster prevention room associated with the security system (S1304). And, the gate control system 150 transmits the emergency state information according to the elevator abnormality to the elevator control system 130, and the elevator control system 130 to the elevator 120, the carrier door 510-1, 510-2) is transmitted (S1305), and at the same time, the closed state of the carrier doors 510-1 and 510-2 is controlled to be maintained. The elevator 120 closes all the carrier doors 510-1 and 510-2 according to the command of the elevator control system 130 (S1306), and turns on the emergency light of the front room 503 to display a warning color according to the emergency state In addition to the box (S1307), a guide broadcast for inducing a person to get off is output. Thereafter, the gate control system 150 checks whether or not the state continues for more than a predetermined time unless a person gets off ( S1308 ). The gate control system 150 sends out an announcement for inducing the person to get off directly from the disaster prevention room or requests that the person visit the corresponding floor and process it (S1309). On the other hand, the gate control system 150 converts the emergency state of the corresponding floor to a normal state when a person alights within a predetermined time (S1310). The gate control system 150 transmits the normal state information to the robot control system 140 , and the robot control system 140 converts the robot 100 to an elevator usable state ( S1311 ). In addition, the elevator control system 130 releases the maintenance of the closed state of the carrier doors 510-1 and 510-2 of the corresponding floor as the person gets off the front room 503 and is converted to a normal state (S1312), The emergency light of the front room space 503 is turned off (S1313).

As described above, according to embodiments of the present invention, it is a robot-only elevator having a front room that can be used as a waiting space and a charging space for the robot. can Furthermore, according to the embodiments of the present invention, the double door separating the robot carrier and the front room, and the front room and the hallway outside the front room can be organically controlled according to the movement of the robot, thereby promoting safety and efficiency in the use of the elevator. have.

The device described above may be implemented as a hardware component, a software component, and/or a combination of the hardware component and the software component. For example, the devices and components described in the embodiments may include a processor, a controller, an arithmetic logic unit (ALU), a digital signal processor, a microcomputer, a field programmable gate array (FPGA), and a programmable logic unit (PLU). It may be implemented using one or more general purpose or special purpose computers, such as a logic unit, microprocessor, or any other device capable of executing and responding to instructions. The processing device may execute an operating system (OS) and one or more software applications running on the operating system. The processing device may also access, store, manipulate, process, and generate data in response to execution of the software. For convenience of understanding, although one processing device is sometimes described as being used, one of ordinary skill in the art will recognize that the processing device includes a plurality of processing elements and/or a plurality of types of processing elements. It can be seen that may include For example, the processing device may include a plurality of processors or one processor and one controller. Other processing configurations are also possible, such as parallel processors.

The software may comprise a computer program, code, instructions, or a combination of one or more thereof, which configures a processing device to operate as desired or is independently or collectively processed You can command the device. The software and/or data may be embodied in any type of machine, component, physical device, computer storage medium or device for interpretation by or providing instructions or data to the processing device. have. The software may be distributed over networked computer systems and stored or executed in a distributed manner. Software and data may be stored in one or more computer-readable recording media.

The method according to the embodiment may be implemented in the form of program instructions that can be executed through various computer means and recorded in a computer-readable medium. In this case, the medium may be to continuously store the program executable by the computer, or to temporarily store the program for execution or download. In addition, the medium may be various recording means or storage means in the form of a single or several hardware combined, it is not limited to a medium directly connected to any computer system, and may exist distributed on a network. Examples of the medium include a hard disk, a magnetic medium such as a floppy disk and a magnetic tape, an optical recording medium such as CD-ROM and DVD, a magneto-optical medium such as a floppy disk, and those configured to store program instructions, including ROM, RAM, flash memory, and the like. In addition, examples of other media may include recording media or storage media managed by an app store that distributes applications, sites that supply or distribute other various software, and servers.

As described above, although the embodiments have been described with reference to the limited embodiments and drawings, various modifications and variations are possible by those skilled in the art from the above description. For example, the described techniques are performed in a different order than the described method, and/or the described components of the system, structure, apparatus, circuit, etc. are combined or combined in a different form than the described method, or other components Or substituted or substituted by equivalents may achieve an appropriate result.

Therefore, other implementations, other embodiments, and equivalents to the claims are also within the scope of the following claims.

Claims (16)

In a building comprising a computer-implemented elevator control system,
The elevator control system,
at least one processor configured to execute computer readable instructions contained in memory
including,
In the building, as controlling a robot-only elevator including at least one carrier on which the robot boards for vertical movement, and an entire room in which the robot waits before boarding the carrier,
by the at least one processor,
Controlling a carrier door that separates the carrier and the front room based on the movement line of the robot and a front door that separates the front room and a corridor outside the front room,
the at least one processor,
When the first robot is waiting at the first position in front of the front door before entering the front room, when it is confirmed that a second robot that is different from the first robot does not exist in the front room, the second robot 1 Controlling the front door to be opened for the robot to enter the front room
A building featuring According to claim 1,
by the at least one processor,
Controlling the other door to open while one of the carrier door and the front door is closed
A building featuring According to claim 1,
An external standby node waiting to enter the front room from outside the front room as a node for controlling the movement line of the robot moving the carrier, the front room, and the hallway, and waiting for boarding the carrier in the front room A layover node, an internal standby node waiting to enter the hallway from the front room after getting off the carrier is defined
A building featuring According to claim 1,
by the at least one processor,
When a request to open the front door is received for the robot to enter or exit the front room, it is checked whether the carrier door is closed,
If the carrier door is in an open state, it waits, and if the carrier door is in a closed state, the front door is controlled to open,
Controlling the front door to close when the robot enters or exits the front room is completed
A building featuring 5. The method of claim 4,
by the at least one processor,
Maintaining the closed state of the carrier door for opening and closing the front chamber door, and then releasing the closed state of the carrier door when the front chamber door is closed after the robot enters or exits the front chamber
A building featuring According to claim 1,
by the at least one processor,
When the carrier arrives on the current floor or the target floor of the robot, it is checked whether the front door is closed,
If the front door is in the open state, wait, and if the front door is closed, control the carrier door to open;
Controlling the carrier door to close when boarding or disembarking of the carrier of the robot is completed
A building featuring 7. The method of claim 6,
by the at least one processor,
Maintaining the closed state of the front door for opening and closing the carrier door, and then releasing the closed state of the front door when the carrier door is closed after the robot gets on or off the carrier
A building featuring According to claim 1,
by the at least one processor,
Controlling the movement of each robot by determining the order of boarding in the front room according to the priority of the robot and other robots
A building featuring According to claim 1,
by the at least one processor,
By the at least one processor, detecting an elevator abnormality due to the entry of a person in the front room,
By the at least one processor, when the elevator abnormality is detected, converting the robot-only elevator to an unusable state
A building featuring In a building including a robot-only elevator,
The robot-only elevator is controlled by a computer-implemented elevator control system,
The elevator control system,
at least one processor configured to execute computer readable instructions contained in memory
including,
In the building, as controlling the robot-only elevator including at least one carrier on which the robot boards for vertical movement, and the front room, which is a space in which the robot waits before boarding the carrier,
by the at least one processor,
Controlling a carrier door that separates the carrier and the front room based on the movement line of the robot and a front door that separates the front room and a corridor outside the front room,
the at least one processor,
When the first robot is waiting at the first position in front of the front door before entering the front room, when it is confirmed that a second robot that is different from the first robot does not exist in the front room, the second robot 1 Controlling the front door to be opened for the robot to enter the front room
A building featuring According to claim 1,
The first position is a node defined to control a movement line of the robot moving the carrier, the front room, and the hallway, and is a position where the first robot waits to enter the front room from outside the front room. being a standby node
A building featuring According to claim 1,
As the robot control system configured to communicate with the elevator control system and control the second robot confirms that the second robot is present at a second position in the front room, the second robot is present in the front room what is confirmed to be
A building featuring 13. The method of claim 12,
The second position is a node defined to control a movement line of the robot moving the carrier, the front room, and the corridor, and the second position is a layover in which the second robot waits for boarding the carrier in the front room. (layover) node or the second robot is an internal standby node waiting to advance from the front room to the hallway after getting off the carrier
A building featuring According to claim 1,
When it is confirmed that the second robot exists in the front room, the first robot is controlled to stand by at the first position
A building featuring In the elevator control method performed by the computer-implemented elevator control system,
wherein the elevator control system comprises at least one processor configured to execute computer readable instructions contained in a memory;
The elevator control method,
To control a robot-only elevator comprising at least one carrier on which the robot boards for vertical movement, and an entire room where the robot waits before boarding the carrier,
Controlling, by the at least one processor, a carrier door that separates the carrier from the front room based on the movement line of the robot, and a front door that separates the front room and a hallway outside the front room
including,
The step of controlling the front room door comprises:
When the first robot is waiting at the first position in front of the front door before entering the front room, when it is confirmed that a second robot that is different from the first robot does not exist in the front room, the second robot 1 An elevator control method for controlling the front door to be opened for the robot to enter the front room. In the elevator control system implemented by a computer,
at least one processor configured to execute computer readable instructions contained in memory
including,
To control a robot-only elevator comprising at least one carrier on which the robot boards for vertical movement, and an entire room where the robot waits before boarding the carrier,
by the at least one processor,
Controlling a carrier door that separates the carrier and the front room based on the movement line of the robot and a front door that separates the front room and a corridor outside the front room,
the at least one processor,
When the first robot is waiting at the first position in front of the front door before entering the front room, when it is confirmed that a second robot that is different from the first robot does not exist in the front room, the second robot 1 Controlling the front door to be opened for the robot to enter the front room
Elevator control system, characterized in that.

Images