JP2021128768A - Agv route search server, agv route search system, agv route search method, program, and recording medium - Google Patents

Abstract

To provide an AGV route search server, an AGV route search system, and an AGV route search method that improve the degree of freedom in layout related to a plurality of self-propelled bodies in a distribution center, and especially make it easy to transport to a destination in the shortest distance (time).SOLUTION: In an AGV system using a plurality of self-propelled bodies 10 and a plurality of grids serving as markers for travelling of the self-propelled bodies 10 in a distribution center, an AGV route search server 20 for searching a path of a predetermined self-propelled body 10 when the self-propelled bodies 10 are self-propelled includes: arithmetic means for virtually calculating coordinates based on a condition for route search; communication means capable of transmitting and receiving data of the coordinates calculated by the arithmetic means in real time between the self-propelled body and the server; and setting means for the self-propelled body 10 that moves by itself based on the coordinates to appropriately reset the data of the coordinates from the communication means based on the condition for route search.SELECTED DRAWING: Figure 1

Description

The present invention relates to an AGV route search server, an AGV route search system, an AGV route search method, a program, and a recording medium based on the fastest pathfinding (Dijkstra's algorithm) as a basic principle.

Conventionally, a conveyor has been used to transport cargo at a distribution center. However, in a distribution center, existing walls and pillars are everywhere, so layout is difficult and the transportation route may be detoured. Moreover, it is difficult to obtain permission from the Fire Service Act, and fixed equipment costs money. Therefore, in recent years, a method has been proposed in which an automatic guided vehicle (hereinafter referred to as AGV) is used to carry luggage to a predetermined place while avoiding existing walls and pillars.

nothing special

However, conventionally, when a plurality of self-propelled bodies are used in the warehouse of a distribution center, if the plurality of self-propelled bodies are close to each other, it becomes difficult to move, and the degree of freedom in layout is rather narrowed. Especially in the case of a standard grid where the grid spacing is set to a fixed size, if the traveling route of the self-propelled body is set while avoiding obstacles when the grid spacing is wide, it will be a large turn and the installation volume of the shelf must be reduced. It doesn't become. Furthermore, if it is determined that the time can be shortened after stopping once before the self-propelled vehicle collides, one of them may select a route to return, which takes more time. Furthermore, it takes a lot of time for the self-propelled body to run on the outer circumference where the shelves are lined up if the grid pitch is reduced so far.

Therefore, the present invention has been devised in view of various existing circumstances as described above, and the degree of freedom in layout of a plurality of self-propelled bodies in a distribution center is improved, and the shortest distance to a destination is particularly short. It is an object of the present invention to provide an AGV route search server, an AGV route search system, an AGV route search method, a program, and a recording medium, which are easy to carry over a distance (short time) and are excellent in terms of safety.

In order to solve the above-mentioned problems, in the present invention, the self-propelled body is used in an AGV system using a plurality of self-propelled bodies and a plurality of grids that serve as markers for running the self-propelled body in the distribution center. It is an AGV route search server for searching a route of a predetermined self-propelled body when it is self-propelled.
The server is a calculation means that virtually calculates coordinates based on conditions for route search, and
A communication means capable of transmitting and receiving coordinate data calculated by the calculation means between the self-propelled body and the server in real time.
A setting means for a self-propelled body that moves by itself based on the coordinates to appropriately reset the coordinate data from the communication means based on the conditions for the route search.
It is characterized by being equipped with.

According to this configuration, a setting means for appropriately resetting the coordinate data from the communication means when the self-propelled body that moves by itself based on the coordinates reaches the area with the obstacle is provided. Based on the conditions for route search, for example, even if a plurality of self-propelled bodies 10 are close to each other, this can be immediately avoided based on the coordinate data reset by the setting means.

The setting means resets the AGV by making the coordinate pitch variable in the area where there is an obstacle.

According to this configuration, the coordinate pitch is made variable and reset. Therefore, when the AGV runs on the outer circumference where the shelves are lined up, the coordinate pitch is increased to make two grids of the start point and the end point. It can be speeded up.

The conditions for the route search include the appearance of obstacles to the running self-propelled body, the running speed for the running self-propelled body, the type of the running self-propelled body, the size of the running self-propelled body, and the like. Number of running self-propelled bodies, running density in a certain area of running self-propelled body, type of shelf, size of shelf, quantity of shelves, quantity density in a certain area of shelf, equipment connected to self-propelled body It is characterized by being conditional on the relationship with.

According to this configuration, the traveling body can be speeded up based on the conditions for route search, and the collection and delivery efficiency of luggage is improved.

The server communicates grid-type commands between the self-propelled body and the server in real time, and in an area without obstacles, the self-propelled body can run on its own based on the grid method, and there are obstacles. In the area, the self-propelled body reduces the grid pitch instead of the grid method.

According to this configuration, it is possible to carry to the destination in the shortest distance (short time) in an area without obstacles, and in an area with obstacles, the grid pitch is reduced to prevent collision with obstacles. You can move while avoiding it, and the efficiency of collecting and delivering luggage is improved. Moreover, it is possible to run without reducing the installation volume of the shelf, and the speed of the self-propelled body 10 can be increased.

The server sends grid-type commands to the self-propelled body to increase or decrease the grid pitch according to the size of the article storage rack.

According to the present invention, it is possible to travel and move while avoiding a collision with a rack for storing articles, and it is possible to improve the efficiency of collecting and delivering luggage, and thus to speed up the AGV.

When an obstacle appears on the running self-propelled body or the running speed on the running self-propelled body changes, the pitch of the coordinate interval is made variable.

According to this configuration, the self-propelled body can travel and move without colliding with an obstacle.

When the type of self-propelled body during running, the size of the self-propelled body during running, the number of self-propelled bodies during running, and the running density in a certain area of the self-propelled body during running change, the self-propelled body If the type and size become smaller and the number of units increases, the interval for adjusting the coordinate pitch is narrowed, and if the number of units per fixed area increases, the interval is also narrowed accordingly.

According to this configuration, even if the number of self-propelled bodies increases, the traveling movement can be smoothly performed without colliding with each other.

For racks, the coordinate pitch spacing is adjusted according to the type, size, quantity, and density per fixed area.

According to this configuration, the self-propelled body can be smoothly moved without colliding with the rack.

If there are other material handling equipment such as conveyors and automated warehouses in the distribution center, and when approaching the material handling equipment, close the intervals and finely control.

According to the present invention, the self-propelled body can be smoothly moved without colliding with the material handling device.

The size of the rack, the size of the self-propelled body, and when the self-propelled body and the rack are crowded in the warehouse, the distance between the grids in the area with obstacles can be changed in a variable manner.

According to this configuration, by making the grid spacing variable, precise running control of the self-propelled body becomes possible, and protection of the self-propelled body is ensured.

In an AGV system using a plurality of self-propelled bodies and a plurality of grids that serve as markers for running the self-propelled bodies in a distribution center, when the self-propelled bodies are self-propelled, a predetermined route of the self-propelled bodies is searched. AGV route search system for
The system is a calculation means for virtually calculating coordinates based on conditions for path search, and
A communication means capable of transmitting and receiving coordinate data calculated by the calculation means between the self-propelled body and the server in real time.
The setting means in which the self-propelled body that moves by itself based on the coordinates appropriately resets the coordinate data from the communication means based on the conditions for the route search, and the communication means are newly renewed by the setting means. It is characterized in that the calculated coordinate data is transmitted to the self-propelled body.

According to this configuration, even if a plurality of self-propelled bodies are close to each other, this can be immediately avoided based on the coordinate data reset by the setting means, and the collision between the self-propelled bodies can be avoided in advance. In addition, it is possible to carry the vehicle to the destination in the shortest distance (short time), and it is possible to easily construct an AGV route search system that improves the efficiency of collecting and delivering luggage.

In an AGV system using a plurality of automatic guided vehicles and a plurality of grids that serve as markers for the automatic guided vehicles in the distribution center, when the automatic guided vehicles are made to run by themselves, a predetermined route of the automatic guided vehicles is searched for. It is an AGV route search method for
The method includes a step of virtually calculating coordinates based on conditions for route search, and
Steps to send and receive the calculated coordinate data between the self-propelled body and the server in real time,
The self-propelled body that moves by itself based on the coordinates includes a step of appropriately resetting the coordinate data based on the conditions for the route search.

According to this configuration, this can be avoided immediately based on the reset coordinate data, collisions between self-propelled bodies can be avoided in advance, and the shortest distance (short) to the destination. It is possible to carry it in time), and it is possible to easily construct an AGV route search method that improves the efficiency of collecting and delivering luggage.

According to the present invention, the degree of freedom in the layout of the self-propelled body in the distribution center is improved, and it becomes easy to carry the self-propelled body to the destination in the shortest distance (short time), which is excellent in terms of safety.

It shows one embodiment for carrying out this invention, (a) is the perspective view of the self-propelled body at the time of Bluetooth (registered trademark) communication, (b) is the perspective view of the self-propelled body at the time of wireless Wi-Fi communication. Is. It is a figure which shows the functional block of this system. It is a figure which shows the status acquisition command. It is a figure which shows the response of the status acquisition command. It is a figure which shows the response of the status acquisition command. It is a figure which shows the response of the status acquisition command. It is a figure which shows the response of the status acquisition command. It is a figure which shows the command of the position identification operation control. It is a figure which shows the response of the command of the position identification operation control. It is a figure which shows the command of the traveling control. It is a figure which shows the command of the driving basic information setting. It is a figure which shows the command of the traveling extension information 1. It is a figure which shows the command of the traveling extension information 2. It is a figure which shows the quantitative operation command. It is a figure which shows the map switching command. It is a figure which shows the course data read / write command. It is a figure which shows the flowchart of this system. It is a figure which shows the software structure. It is a figure which shows the local coordinate system of the AGV system. It is a figure which shows the 2D coordinate system. FIG. 21 (a) is a diagram showing a two-dimensional coordinate / 2D code comparison table, and FIG. 21 (b) is a diagram showing the correspondence between the two-dimensional coordinates / 2D code on the AGV management software screen. It is a figure which shows the abnormal message sequence. It is a figure which shows the detail of a message header. It is a figure which shows the detail of an ACK message. It is a figure which shows the detail of a manual operation. It is a figure which shows the detail of the automatic operation request. It is a figure which shows the operation at the time of a stop. It is a figure which shows the detail of the automatic operation request response. It is a figure which shows the detail of the status data. It is a figure which shows the default value at the time of starting the AGV system. It is a figure which shows the detail of the operation command. It is a figure which shows the operation of the emergency stop / release of an AGV system. It is a figure which shows the outline sequence. It is a figure which shows the message sequence at the time of starting the AGV system. It is a figure which shows the message sequence at the time of a normal operation. It is a figure which shows the message sequence which did not respond to the connection disconnection determination. It is a figure which shows the message sequence which does not require the connection disconnection determination. It is a figure which shows the message sequence at the time of an abnormality occurrence. It is a figure which shows the connection return sequence. It is a figure which shows the message undelivered sequence. It is a figure which shows the sequence of error correction. It is a figure which shows the sequence at the time of normal termination. It is a figure which shows the sequence at the time of abnormal termination. It is a figure which shows the sequence of a cycle stop / release (restart). It is a figure which shows the sequence of a cycle stop / release (order clear). It is a figure which shows the sequence of an emergency stop / release. It is a figure which shows the sequence of the emergency stop release. It is a figure which shows the sequence of a manual operation mode.

Hereinafter, an embodiment of the AGV route search model (AGV route search server, AGV route search system, AGV route search method) according to the present invention will be described in detail with reference to the drawings. In this embodiment, the route is one road on each side, but it is assumed that there is a right to pass two routes.

As shown in FIG. 1, the AGV route search model according to the present embodiment includes a self-propelled body 10 and a server 20. The self-propelled body 10 relates to a self-propelled trolley (self-propelled body 10) that travels based on the grid and its control system, and the self-propelled body 10 is a self-propelled trolley of the self-propelled body 10. That is. The self-propelled vehicle 10 is an automatic guided vehicle that travels while estimating its own position based on a map created by a server 20 commanding a map of features in the traveling area by its own laser sensor.

The server 20 is a system server of the AGV path search model, and is housed in the system monitoring PC 30. In an AGV system using a self-propelled body 10 and a plurality of grids that serve as travel marks for the self-propelled body 10, the self-propelled body 10 that moves by itself based on the coordinates has coordinates based on the conditions for the route search. Reset the data as appropriate (setting means). As shown in FIG. 1, the communication between the self-propelled body 10 and the server 20 is performed by Bluetooth communication or wireless Wi-Fi communication. This specification is supported by updating the firmware of the standard self-propelled vehicle to dedicated software. That is, as shown in FIG. 18, the software configuration of the present embodiment includes the AGV travel optimization software 31 and the AGV management software 32 in the system monitoring PC 30, and the wireless communication software in the autonomous travel control CPU 12 of the self-propelled vehicle 10. 13. The inter-grid movement control software 14 and the control software 16 in the base robot 15 are connected by USB. Then, a message is transmitted and received between the system monitoring PC 30 which is the server 20 and the self-propelled body 10, connection confirmation is performed by sending and receiving a regular cycle message, and message arrival confirmation is performed by a response message.

In the wireless Wi-Fi communication of the communication interface, the communication standard, frequency band, communication speed, security, communication form, and communication cycle are set, and both Bluetooth communication and wireless Wi-Fi communication use the same communication format. All commands operate in response to the command from the server 20 from the self-propelled body 10. Also, the data format that uses multiple bytes is big endian.

As a condition for route search, when an obstacle appears on the running self-propelled body 10 or the running speed on the running self-propelled body changes, the pitch of the coordinate interval is made variable and the running self-propelled body 10 is changed. When the type, size, number of units, and traveling density in a certain area change, the type and size of the self-propelled body 10 becomes smaller, and as the number of units increases, the interval for adjusting the coordinate pitch becomes narrower and the constant area. As the number of units per unit increases, the interval becomes narrower accordingly. Also, for shelves, the coordinate pitch interval can be adjusted according to the type, size, quantity, and density per fixed area. Furthermore, if there are other material handling equipment such as conveyors and automated warehouses in the distribution center, there is a possibility of connecting to these equipment, and even in that case, it is necessary to control the interval of the coordinate pitch. Especially when approaching material handling equipment, it is necessary to close the intervals and finely control.

As shown in FIG. 17, when the server 20 virtually calculates the coordinates based on the conditions for the route search (step 10: calculation means), the server 20 transfers the calculated coordinate data between the self-propelled body 10 and the server. It has a communication means capable of transmitting and receiving in real time, and has a transmission means (step 20) of the server 20 for transmitting to (step 30) as a receiving means of the self-propelled body 10. The self-propelled body 10 starts traveling based on the calculated coordinate data (step 40). The AGV local coordinate system is defined below.

That is, as shown in FIG. 19, the origin: the self-propelled body 10 position (2D code position directly below), the U axis: the self-propelled body 10 traveling axis used during traveling, and a parallel axis with the X axis. C-axis: A rotation axis with the front surface of the self-propelled body 10 at 0 °, which is used during rotation, and is a rotation axis centered on the Z-axis. The 2d coordinate system is defined below. That is, as shown in FIGS. 20, 21 (a), and 21 (b), it is a Cartesian coordinate system of a plane having X and Y axes, and the coordinates are in grid (2D code of the floor surface) unit. FIG. 21A is a current two-dimensional coordinate / 2D code correspondence table of the AGV management software 32, the left end and the lowest are two-dimensional coordinates, and the others are 2D codes. FIG. 21B shows the correspondence between the 2D code on the 32 screen of the AGV management software and the two-dimensional coordinates.

Based on the coordinates, it is determined whether or not the self-propelled body 10 that moves by itself has reached an area with an obstacle (step 50). If this determination is not satisfied, the vehicle travels based on the coordinate data. If the determination is satisfied, the information on the presence of obstacles is transmitted from the self-propelled body 10 (step 60) to the server 20 (step 70). Taking this as an opportunity, the coordinate data from the transmission means is appropriately reset (step 80: setting means). That is, the grid pitch is reduced. This setting data is transmitted to the self-propelled body 10 (step 90), and the self-propelled body 10 receives this (step 100).

Further, the server 20 transmits a grid-type command to the self-propelled body 10, and expands or contracts the grid pitch according to the size of the article storage rack. In addition, the server 20 makes it possible to change the spacing of the grids in a variable manner when the server 20 is in an area with obstacles. That is, a grid method command is transmitted to the self-propelled body 10, the self-propelled body 10 can be self-propelled based on the grid method when it is in an area without obstacles, and when the rack size is large, it is self-propelled. If the size of the self-propelled body 10 is large, the self-propelled body 10 and the rack are crowded in the warehouse, or if the self-propelled body 10 is in an area with obstacles, the self-propelled body 10 is replaced with a reduced grid instead of the grid method. Is also good. Then, the reduced grid in the area with obstacles may make the coordinate pitch variable and the size of the grid method variable.

Next, the interface specifications of the grid type AGV system will be described. First, the message format will be described with reference to FIG. The message format consists of a message header and a message body. That is, the message header includes start code, version, message type, message ID, sender ID, recipient ID, message number, return code, message length, date and time of transmission: year, month, day, hour, minute, second, millisecond. It has seconds, a message body, and an exit code. The return code in the message header is the result of validation of the received message and consists of a request / notification message and an ACK message.

As for the message sequence when the abnormal message occurs, as shown in FIG. 22, the AGV management software 32 sends the abnormal message to the self-propelled body 10. The self-propelled body 10 verifies the validity of the received message. The self-propelled body 10 sends an ACK return code, and the movement / rotation is stopped. The AGV management software 32 stops the operation of the self-propelled body 10 and notifies the user. As shown in FIG. 24, the ACK message includes a start code, a version, a message type, a message ID, a sender ID, a recipient ID, a message number, a return code, a message length, and a date and time of transmission: year, month, day, hour, It has minutes, seconds, milliseconds, and an exit code. In the definition data (MVCD), the self-propelled body 10 sets the system clock to the date and time notified by this message. After receiving the definition data, the "AGV status" of the status data (MVST) is set to "definition data set". Immediately after the self-propelled body 10 is started, the operation mode inside the self-propelled body 10 is set to "1: automatic".

Next, as shown in FIG. 25, the manual operation (MVMO) has the order ID, the speed in the U direction (straight), the U traveling direction, the number of moving grids in the U direction, the speed in the C direction (rotation), and the C rotation direction. It is disclosed together with the length, data, and description, and when there is an operation conflict, that is, when a single manual operation includes a plurality of operations, the self-propelled body 10 considers it as an abnormal message and does not execute the operation. At that time, the return code of the ACK message is "GE".

As shown in FIG. 26, the automatic operation request (MVAO) includes an order ID, a speed in the U direction (straight), a number of moving grids in the U direction, a speed in the C direction (rotation), a C rotation direction, a stop, a restart order ID, and a higher order ID. Is disclosed along with the type, length, data and description. If a single automatic driving request includes a plurality of requests (move, rotate, stop) at the time of request conflict, the self-propelled body 10 considers it as an abnormal message. The stop instruction is executed with priority over the manual operation and automatic operation request during execution. As for the self-propelled body 10 operation of the stop instruction, each instruction of cycle stop, stop release (restart), and stop release (order clear) is disclosed together with the operation. When the self-propelled body 10 receives a message other than a data request and an automatic operation request other than the stop release during the cycle stop, it is regarded as an abnormal message and is not executed. At that time, the return code of the ACK message is "GE". During the stop, the "AGV status" of the status data is "cycle stopped". In the restart order ID, the order ID of the automatic operation request to be restarted from the AGV management software 32 is specified when the stop is released (restarted). If it does not match the suspended order ID, it is regarded as an abnormal message and is not restarted. At that time, the return code of the ACK message is "GE".

As shown in FIG. 28, the automatic operation request response (MVAR) discloses an order ID, an option, a response type, an execution status, an error status, and a higher order ID together with a type, a length, data, and a description. The self-propelled body 10 that has notified the occurrence of the error in the error status and the AGV management software 32 that has received the notification execute the operation at the time of abnormality. The data request (MVDR) is for survival confirmation and status monitoring of manual operation / automatic operation request.

As shown in FIG. 29, the status data (MVST) includes 2D code, ANGLE, misalignment, distance, direction, operation mode, right speed control value, left side speed control value, right side speed measurement value, left side speed measurement value, and distance. Sensor ch1 measurement distance, distance Sensor ch2 measurement distance, battery voltage, remaining battery level, failure code, error code, AGV status, execution order ID, order execution status, execution upper order ID, respectively, type, length, data, description Is disclosed with. The self-propelled body 10 that has notified the occurrence of an error with a failure code and an error code, and the AGV management software 32 that has received the notification execute an operation at the time of abnormality. The status data at the time of starting the self-propelled body 10 is as shown in FIG.

As shown in FIG. 31, the operation command (MVOC) is disclosed together with the order ID and the command along with the type, length, data, and description. The AGV that has received the error correction command executes fixed point error correction. The AGV management software 32 detects the correction result from the "2D code", "ANGLE", and "positional deviation" of the status data. Further, the operation of the self-propelled body 10 at the time of emergency stop and release is shown in FIG. 32. During an emergency stop, if the self-propelled body 10 receives a message other than a data request or an operation command other than the stop release, it is regarded as an abnormal message and is not executed. At that time, the return code of the ACK message is "GE". During the stop, the "AGV status" of the status data is "emergency stop".

Next, the outline of the communication sequence will be described with reference to FIG. 33. The outline sequence of communication from the start of the self-propelled body 10 to the operation of the self-propelled body 10 is shown below. When the self-propelled body 10 is started, the AGV management software 32 detects when the self-propelled body 10 is started. The AGV management software 32 sets the definition data in preparation for the operation of the self-propelled body 10, and the self-propelled body 10 receives the definition data. In the survival confirmation, the AGV management software 32 starts the acquisition of the self-propelled body 10 state at a fixed cycle. In the error correction, the AGV management software 32 corrects the error in the position and direction of the self-propelled body 10. In the operation of the self-propelled body 10, the AGV management software 32 sets the operation mode of the self-propelled body 10. The AGV management software 32 instructs the self-propelled body 10 to move and rotate. The AGV management software 32 acquires the state of the self-propelled body 10 at regular intervals and monitors the operating state. The self-propelled body 10 notifies the result at the end of the order of the automatic driving request (automatic driving request only). After the self-propelled body 10 is started, the self-propelled body 10 transmits the status data to the AGV management software 32. After receiving the AGV management software 32, the definition data is transmitted, and the survival confirmation is started for the corresponding self-propelled body 10. Survival confirmation is performed by data request and status data.

The normal survival confirmation message sequence is as shown in FIG. The connection disconnection determination message sequence when there is no response from the self-propelled body 10 is as shown in FIG. The connection disconnection determination message sequence when there is no request from the AGV management software 32 is as shown in FIG. 37. The message sequence when the abnormality of the self-propelled body 10 is notified is as shown in FIG. 38.

As shown in FIG. 39, in the connection return message sequence, first, when the connection between the AGV management software 32 and the self-propelled body 10 is disconnected, the self-propelled body 10 transmits status data at regular intervals until there is a response. The self-propelled body 10 sends status data to the AGV management software 32, and the AGV management software 32 causes the self-propelled body 10 to receive an ACK message. The self-propelled body 10 stops the transmission of status data at regular intervals. This procedure is repeated until the connection is restored. After that, survival confirmation is resumed.

Next, the message sequence in which the message is not delivered will be described with reference to FIG. 40. If the ACK message is not received within the specified time after sending the request / notification message, it is determined that the message has not been delivered and the message is resent. First, the AGV management software 32 retransmits a predetermined number of messages when there is no ACK message within a predetermined time from the self-propelled body 10 from the start of waiting for the ACK message. This procedure is repeated until the connection is restored. After that, when the AGV management software 32 determines that there is no ACK message in the predetermined number of transmissions, it determines that the connection is disconnected.

If it is determined that error correction is necessary after starting the self-propelled body 10, the AGV management software 32 instructs the error correction. First, in the survival confirmation, the AGV management software 32 executes a data request to the self-propelled body 10. The self-propelled body 10 starts the status data. When it is determined that the execution status has not ended, the AGV management software 32 detects that the error correction is being executed. When the error correction of the self-propelled body 10 is completed, the AGV management software 32 re-executes the data request to the self-propelled body 10. The self-propelled body 10 starts the status data. When it is determined that the execution status has ended, the AGV management software 32 detects the completion of the error correction.

The sequence at the time of normal termination of the order of the automatic operation request is as shown in FIG. Further, the sequence at the time of abnormal termination of the order of the automatic operation request is as shown in FIG. 43. Further, as shown in FIG. 44, the message sequence for stopping / canceling the cycle at the time of resuming the order is, first, in the case of stopping the self-propelled vehicle 10, the AGV management software 32 instructs an automatic operation request (cycle stop). The self-propelled body 10 sets the AGV status during the cycle stop, pauses the running order, moves / stops rotating on the nearest grid, and ends the cycle stop execution. The AGV management software 32 causes the self-propelled vehicle 10 to execute an automatic operation request response (notification of end of cycle stop order). In the case of releasing the stop of the self-propelled vehicle 10, the AGV management software 32 instructs an automatic operation request (release of stop). The self-propelled body 10 revives the pause order. The AGV management software 32 causes the self-propelled vehicle 10 to execute an automatic operation request response (stop release order end notification). The self-propelled body 10 releases the AGV status during the cycle stop. After that, the order resumes.

As shown in FIG. 45, the message sequence of the cycle stop / release at the time of clearing the order is as follows. 10 clears the order. After that, when an automatic operation request (new order) is made, the self-propelled body 10 executes the new order. The emergency stop / release message sequence is as shown in FIGS. 46 and 47. The message sequence in the manual operation mode is as shown in FIG.

In FIG. 46, in the case of an AGV emergency stop, the AGV management software 32 requests the self-propelled body 10 to perform an emergency stop operation command. The self-propelled body 10 sets the AGV status during the emergency stop, and the emergency stop is started. The survival confirmation executes a data request to the self-propelled body 10, and notifies the AGV management software 32 that the status of the self-propelled body 10 has not been completed. The AGV management software 32 detects that an emergency stop is being executed. The self-propelled body 10 stops moving / rotating on the spot, and when the emergency stop is completed, the AGV management software 32 sends a data request to the self-propelled body 10. The self-propelled body 10 notifies the AGV management software 32 that the status has ended. The AGV management software 32 detects the completion of the emergency stop.

In FIG. 47, in the AGV emergency stop release, the AGV management software 32 notifies the self-propelled body 10 of the operation command for the emergency stop release. The self-propelled body 10 starts the emergency stop release. In the survival confirmation, the AGV management software 32 transmits a data request to the self-propelled body 10, and the self-propelled body 10 is sent to the AGV management software 32 if the status is not completed. The AGV management software 32 detects that the emergency stop release is being executed. The self-propelled body 10 advances to the top of the 2D code at a very small speed, reads the 2D code, and then stops. When the self-propelled body 10 completes the release of the emergency stop, the self-propelled body 10 releases the emergency stop of the AGV status. When a data request is sent from the AGV management software 32 to the self-propelled body 10, the self-propelled body 10 notifies the AGV management software 32 that the status has been completed. The AGV management software 32 detects the completion of the emergency stop release. After that, the self-propelled body 10 receives an automatic operation request (new order) from the AGV management software 32, and the self-propelled body 10 executes the new order.

In FIG. 48, it is not executed when the operation mode is already manual, and the AGV management software 32 notifies the self-propelled body 10 of the operation mode setting. In the survival confirmation, when a data request is sent from the AGV management software 32 to the self-propelled body 10, the status is not completed and the self-propelled body 10 is sent to the AGV management software 32. The AGV management software 32 detects that the manual operation is being executed. The self-propelled body 10 completes the manual operation. Further data requests are sent from the AGV management software 32 to the self-propelled body 10. The self-propelled body 10 notifies the AGV management software 32 that the execution status has been completed. The AGV management software 32 detects the completion of the manual operation.

Next, the functional blocks of this system will be described. As shown in FIG. 2, the self-propelled body 10 provided in the AGB 11 has a control unit 10A and a communication unit 10B (reception means) of the communication interface, and the server 20 has the control unit 20A and the communication unit of the communication interface. A status acquisition command 21, a destination instruction command 22 (calculation means), a quantitative operation command 23, a map switching command 24 (setting means), and a course data read / write command 25 are set as a command list over 20B (transmission means). These commands are transmitted from the communication unit 20B, which is the transmission means of the server 20, to the communication unit 10B, which is the reception means of the self-propelled body 10.

First, as shown in FIG. 3, a status acquisition command 21 such as a sequence number, a self-propelled body general-purpose I / O (output) operation, and a condition determination flag is transmitted from the server 20 to the self-propelled body 10.

Four responses from the self-propelled body 10 are returned to the command from the server 20. As shown in FIG. 4, the X coordinate, Y coordinate, angle and condition determination flag of the destination are returned.

Further, as shown in FIG. 5, error information, operation setting information, battery level, battery voltage, Wi-Fi RSSI, positioning reliability, additional error information, and running course number are returned.

Further, as shown in FIG. 6, the motor current on the right axis, the motor current on the left axis, the marker number, the self-propelled body general-purpose I / O (output) operation, and the self-propelled body general-purpose I / O (input) are returned. ..

Further, as shown in FIG. 7, the self-propelled body input information and the sequence number are returned.

Next, the destination instruction command 22 (calculation means) is transmitted from the server 20 to the self-propelled body 10. At this time, the server 20 virtually calculates the coordinates corresponding to the position of the rack in the refrigerator. As shown in FIG. 8, as the position identification operation control, the position identification control code, the X coordinate of the course start point, and the Y coordinate of the course start point are transmitted.

As shown in FIG. 9, the execution result, the current map number, and the permission information are returned from the self-propelled body 10 to the server 20.

Next, as shown in FIG. 10, the control code, the X coordinate of the destination, the Y coordinate of the destination, and the angle of the destination are transmitted from the server 20 to the self-propelled body 10 as traveling control, and the vehicle self-propells. The execution result is returned from the body 10 to the server 20.

Next, as shown in FIG. 11, the server 20 transmits the vehicle direction, speed, arc radius, acceleration time and deceleration time, and travel course number as basic travel information settings to the self-propelled body 10. The execution result is returned from the body 10 to the server 20.

Next, as shown in FIG. 12, from the server 20 to the self-propelled body 10, as the travel extension information 1, the obstacle avoidance direction, the minimum avoidance distance, the maximum avoidance distance, and the in-position range (the self-propelled body is the target). The distance to be determined to have been reached), the turning speed, the turning acceleration, and the turning deceleration are transmitted, and the execution result is returned from the self-propelled body 10 to the server 20.

Next, as shown in FIG. 13, from the server 20 to the self-propelled body 10, the obstacle detection setting, the obstacle non-detection setting (other than after), the later obstacle detection setting, and the rear as the travel extension information 2. The obstacle non-detection setting is transmitted, and the execution result is returned from the self-propelled body 10 to the server 20.

After all the commands of the position identification operation control, the running control, the basic running information setting, the running extension information 1 and the running extension information 2 are normally received, the self-propelled body 10 starts the automatic operation.

Next, the quantitative operation command 23 is transmitted from the server 20 to the self-propelled body 10. That is, as shown in FIG. 14, the self-propelled body provides information on the operation command, which is the quantitative operation command 23, the obstacle detection setting other than the rear, the obstacle detection setting after, the acceleration time and the deceleration time, before and after the movement, and the movement turn. Send to 10. The execution result is returned from the self-propelled body 10 to the server 20.

Next, the map switching command 24 (setting means) is transmitted from the server 20 to the self-propelled body 10. That is, when the self-propelled AGV reaches the area with the obstacle, the pitch of the coordinate data from the server 20 is made variable and reset as appropriate. In an area with obstacles, the AGV is replaced with a reduced grid instead of the grid method. As shown in FIG. 15, the map number setting, the X coordinate switching coordinate designation, the Y coordinate switching coordinate designation, and the angle switching coordinate designation are transmitted to the self-propelled body 10. The execution result is returned from the self-propelled body 10 to the server 20. This result is the result of whether the command was accepted normally.

Next, the course data read / write command 25 is transmitted from the server 20 to the self-propelled body 10. That is, the course data stored on the self-propelled body 10 is read / written.

As shown in FIG. 16, R / W for designating read / write, course number for specifying the target course number, NUM for specifying data to be read / rewritten, read data in the upper row and write data 6 to 13 in the lower row. Is sent. The execution result is returned from the self-propelled body 10 to the server 20. The result is R / W that specifies read / write, course number that returns the target course number, NUM that returns the read / rewritten data NUM, and read data in the upper row and write data 6 to 13 in the lower row. Will be replied. Since it is not possible to send and receive all the course data in one packet, the NUM is incremented and specified, and the course data is sent and received a plurality of times.

When the QR code (registered trademark) is pasted corresponding to each rack position in the refrigerator, the amount of deviation when passing through the QR code (registered trademark) is detected and corrected for the next QR code (registered trademark). Run. This is traveling control in a relative coordinate system, and the self-propelled body 10 is equipped with a QR code (registered trademark) reader.

When the virtual marker is arranged corresponding to each rack position in the refrigerator as in the QR code (registered trademark), the deviation amount is detected and corrected when the virtual marker is passed, and the vehicle travels to the next virtual marker. .. That is, it is positioned with respect to the virtual marker in absolute coordinates. It also moves at the shortest distance with respect to the given X-coordinate, Y-coordinate, and angle Θ. The accuracy of the absolute coordinate system drops due to landscape changes such as people, AGVs, forklifts, and moving shelves.

The self-propelled body 10 can be used for transportation, for picking, and various forms can be considered depending on the use. In particular, the top plate portion is in line with the purpose as shown below. Since various attachment-type devices are provided, the form has many variations like a truck bed.
(1) Form in which the top plate moves up and down: For example, a self-propelled body capable of moving the top plate up and down by providing a vertical movement mechanism consisting of a telesco (registered trademark) pick mechanism and a pantograph mechanism under the top plate. A solution to operate is conceivable. For example, a self-propelled body sneaks under a plurality of shelves provided in a distribution center, and the shelves are lifted and fixed by a vertical movement mechanism of a top plate to be fixed at a desired place (for example, GTP station GTP: Goods to person). It is a solution that carries the entire shelf.
(2) Solution using two types, one with a crane on the top plate of the self-propelled body and the other with a basket on the top plate: The crane self-propelled body stops in front of the shelf, takes out the goods from the shelf, and the basket itself. It is a solution in which an article is put into a basket of a traveling body and the self-propelled basket carries the article to a GTP station.
(3) Solution using a self-propelled body with a conveyor (belt conveyor or roller conveyor) on the top plate: For example, a space (article receiving port) where the self-propelled body can stop is provided on the transport line in the distribution center. It is a solution that receives the goods sent from the transport line at the goods receiving port, transfers them to the conveyor on the top plate, and transports them to the GTP station.
(4) Solution using a self-propelled body with a structure in which the top plate can be tilted to both sides like a butterfly valve around the center line of the self-propelled body: Similar to the solution in (3), the self-propelled body receives goods on the transport line. After receiving the goods by mouth, the top plate moves horizontally to a destination such as a GTP station. There is a hole in the destination, and the solution is to tilt the top plate toward the hole and drop it. In many cases, a means for transporting to another place such as a conveyor line or a truck bed is provided under the hole.
(5) Solution in which the self-propelled bodies are connected and transported: The self-propelled bodies may not only run independently, but may also be transported by connecting the self-propelled bodies to each other. Since the length of the self-propelled vehicle becomes longer due to the connection, fine control by the variable grid is useful for avoiding collisions between self-propelled vehicles and avoiding collisions with other articles.
(6) Solution that mixes (3) and (5): A conveyor is formed on the top plate of the self-propelled body in a direction 90 degrees different from the traveling direction, and a plurality of these self-propelled bodies are connected in the traveling direction. It is a solution that is arranged in a circle. Such a conveyor-type self-propelled body solution will have the same function as the cross-belt type sorter operated at airports, etc., and a circular rail for running will be provided on the floor like the cross-belt type sorter. Since it is not necessary, it can be installed easily and quickly, there are few restrictions on the installation location, and since it is easy to increase and disassemble the self-propelled body, it also has the advantage of being easy to handle in the event of a failure and maintenance. many.
(7) Solution that the self-propelled body follows the movement of the person: In the case of the solution of (2), the crane self-propelled body is used, but the person moves the basket self-propelled body to the shelf for picking purpose and picks. It may be a solution in which the basket self-propelled body moves together with a person by putting the goods in the basket. It is also useful when you have to move multiple large luggage by yourself at an airport or the like.
As described above, since the grid pitch can be changed, fine control such as collision avoidance becomes possible, which is excellent in terms of safety.

The processing programs such as the status command, destination instruction command, quantitative operation command, map switching command, and course data read / write command described above are not stored in the memory (ROM) in advance, but are recorded in an appropriate recording medium. You may leave it. In this case, the control unit 20A of the server 20 reads and acquires the processing program, and the control unit 20A executes the program after the acquisition.

Although not illustrated one by one, the present invention is carried out with various modifications within a range that does not deviate from the gist thereof.

10 ... Self-propelled body 10A ... Control unit 10B ... Communication means (reception means)
11 ... AGV system 12 ... Autonomous driving control CPU
13 ... Wireless communication software 14 ... Inter-grid movement control software 15 ... Base robot 16 ... Control firmware 20 ... Server (server)
20A ... Control unit 20B ... Communication means (transmission means)
21 ... Status acquisition command 22 ... Destination instruction command (calculation means)
23 ... Quantitative operation command 24 ... Map switching command (setting means)
25 ... Course data read / write command 30 ... PC for system monitoring
31 ... AGV driving optimization shift wear 32 ... AGV management software

Claims (24)

In an AGV system using a plurality of automatic guided vehicles and a plurality of grids that serve as markers for the automatic guided vehicles in the distribution center, when the automatic guided vehicles are made to run by themselves, a predetermined route of the automatic guided vehicles is searched for. AGV route search server for
The AGV pathfinding server is a calculation means that virtually calculates coordinates based on conditions for pathfinding, and
A communication means capable of transmitting and receiving coordinate data calculated by the calculation means between the self-propelled body and the AGV path search server in real time.
A setting means capable of causing the self-propelled body to move by itself based on the coordinates to expand or contract the grid pitch of the coordinates from the communication means based on the conditions for the route search.
An AGV pathfinding server characterized by being equipped with. By reducing the grid pitch of the coordinates by the setting means, the self-propelled body can avoid the obstacle without making a large turn in the area with the obstacle, and by expanding the grid pitch of the coordinates. The AGV route search server according to claim 1, wherein the self-propelled body can travel on the shortest route to the destination. The conditions for the route search include the appearance of obstacles to the self-propelled body during traveling, the traveling speed of the self-propelled body during traveling, the type of the self-propelled body during traveling other than the self-propelled body, and the like. The size of the other running self-propelled body, the number of the other running self-propelled bodies, the running density in a certain area of the other running self-propelled body, the type of shelf, the size of the shelf, The AGV route search server according to claim 1, wherein the number of shelves, the quantity density in a certain area of the shelves, and the relationship between the self-propelled body and the device connected to the self-propelled body are conditions. The AGV pathfinding server communicates grid-type commands between the self-propelled body and the AGV path-finding server in real time, and the self-propelled body can self-propell based on the grid method in an unobstructed area. The AGV path search server according to claim 1, wherein in an area with an obstacle, the self-propelled body reduces the grid pitch of the coordinates instead of the grid method. The AGV path search server according to claim 1, wherein the AGV path search server transmits a grid-type command to the self-propelled body and expands or contracts the grid pitch of the coordinates according to the size of the article storage rack. .. The AGV path search server according to claim 3, wherein when an obstacle appears on the traveling body or the traveling speed of the traveling body changes, the grid pitch of the coordinates is made variable. The type of the self-propelled body during running, the size of the self-propelled body during running, the number of self-propelled bodies during another running, and the running density in a certain area of the other running self-propelled body change. In such a case, if the type and size of the other self-propelled body becomes smaller and the number of the self-propelled bodies increases, the interval for adjusting the grid pitch of the coordinates is narrowed, and if the number of the self-propelled bodies per fixed area increases, the interval is narrowed accordingly. The AGV route search server according to claim 3, wherein the interval is also narrowed. ..
The AGV path search server according to claim 3, wherein the grid pitch of the coordinates is adjusted according to the type, size, quantity, and density per fixed area of the rack. The AGV route search according to claim 3, wherein when there are other material handling equipment such as a conveyor or an automated warehouse in the distribution center, and when approaching the material handling equipment, the conditions for the route search are finely controlled at close intervals. server. The fourth aspect of claim 4, wherein the size of the rack, the size of the self-propelled body, and the grid pitch of the coordinates in an area with an obstacle when the self-propelled body and the rack are crowded in the warehouse can be changed. AGV pathfinding server. In an AGV system using a plurality of self-propelled bodies and a plurality of grids that serve as markers for running the plurality of self-propelled bodies in a distribution center, when the self-propelled bodies are self-propelled, a predetermined self-propelled body route is taken. An AGV route search system for searching,
The AGV pathfinding system includes a calculation means that virtually calculates coordinates based on conditions for pathfinding, and
A communication means capable of transmitting and receiving coordinate data calculated by the calculation means between the plurality of self-propelled bodies and the AGV path search server in real time.
The plurality of self-propelled bodies that self-propelled based on the coordinates are provided with a setting means capable of expanding or contracting the grid pitch of the coordinates from the communication means based on the conditions for the route search.
The communication means is an AGV path search system characterized in that data of coordinates newly calculated by the setting means is transmitted to the plurality of self-propelled bodies. In an AGV system using a plurality of self-propelled bodies and a plurality of grids that serve as markers for running the plurality of self-propelled bodies in a distribution center, when the self-propelled bodies are self-propelled, a predetermined self-propelled body route is taken. This is an AGV route search method using an AGV route search server for searching.
The AGV path search method includes a step of virtually calculating coordinates based on conditions for path search, and a step of virtually calculating coordinates.
A step of transmitting and receiving the calculated coordinate data between the plurality of self-propelled bodies and the AGV path search server in real time, and
An AGV path search method, characterized in that the plurality of self-propelled bodies that move by themselves based on the coordinates include a step of expanding or contracting the grid pitch of the coordinates based on the conditions for the path search. .. In an AGV system using a plurality of self-propelled bodies and a plurality of grids that serve as markers for running the self-propelled bodies in a distribution center, when the self-propelled bodies are self-propelled, a predetermined route of the self-propelled bodies is searched. A program for operating a computer that is an AGV route search server for
The computer
An arithmetic means that virtually calculates coordinates based on conditions for route search,
A communication means capable of transmitting and receiving coordinate data calculated by the calculation means between the self-propelled body and the AGV path search server in real time.
A setting means capable of causing the self-propelled body to move by itself based on the coordinates to expand or contract the grid pitch of the coordinates from the communication means based on the conditions for the route search.
A program characterized by functioning as. By reducing the grid pitch of the coordinates, the setting means can avoid the obstacle without causing the self-propelled body to make a large turn in an area with an obstacle, and expands the grid pitch of the coordinates. The program according to claim 13, wherein the self-propelled body can travel the shortest route to the destination. The conditions for the route search include the appearance of obstacles to the running body, the running speed of the running body, and the type of the running body different from the running body. The size of the other running self-propelled body, the number of the other running self-propelled bodies, the running density in a certain area of the other running self-propelled body, the type of shelf, the size of the shelf, The program according to claim 13, which is conditioned on the quantity of shelves, the quantity density in a certain area of shelves, and the relationship between the self-propelled body and the device connected to the self-propelled body. The AGV pathfinding server communicates grid-type commands between the self-propelled body and the AGV path-finding server in real time, and the self-propelled body can self-propell based on the grid method in an unobstructed area. The program according to claim 13, wherein in an area with obstacles, the self-propelled body further functions the computer so as to reduce the grid pitch of the coordinates instead of the grid method. Claim that the AGV pathfinding server further functions the computer to send grid-type commands to the self-propelled body to increase or decrease the grid pitch of the coordinates according to the size of the article storage rack. The program described in 13. The fifteenth aspect of claim 15, wherein the computer further functions so as to make the grid pitch of the coordinates variable when an obstacle appears with respect to the traveling body or the traveling speed of the traveling body changes. Program. The type of the self-propelled body during running, the size of the self-propelled body during running, the number of self-propelled bodies during another running, and the running density in a certain area of the other running self-propelled body change. In such a case, if the type and size of the other self-propelled body become smaller and the number of the self-propelled bodies increases, the interval for adjusting the grid pitch of the coordinates is narrowed, and if the number of the self-propelled bodies per fixed area increases, the interval is narrowed accordingly. 15. The program of claim 15, which further causes the computer to function so that the intervals are also narrowed. The program according to claim 15, wherein the computer further functions to adjust the grid pitch of the coordinates according to the type, size, quantity, and density per fixed area of the rack. If there are other material handling equipment such as conveyors and automated warehouses in the distribution center, and when approaching the material handling equipment, a request to further function the computer to finely control the conditions for the route search at close intervals. Item 15. The program according to Item 15. The size of the rack, the size of the self-propelled body, and the computer so that when the self-propelled body and the rack are crowded in the warehouse, the grid pitch of the coordinates in the area with obstacles can be changed. The program of claim 16 for further functioning. In an AGV system using a plurality of self-propelled bodies and a plurality of grids that serve as markers for running the plurality of self-propelled bodies in a distribution center, when the self-propelled bodies are self-propelled, a predetermined self-propelled body route is taken. A program for operating a computer in an AGV route search system for searching.
The computer
An arithmetic means that virtually calculates coordinates based on conditions for route search,
A communication means capable of transmitting and receiving coordinate data calculated by the calculation means between the plurality of self-propelled bodies and the AGV path search server in real time.
The plurality of self-propelled bodies that move by themselves based on the coordinates function as setting means capable of expanding or contracting the grid pitch of the coordinates from the communication means based on the conditions for the route search.
The communication means is a program characterized in that data of coordinates newly calculated by the setting means is transmitted to the plurality of self-propelled bodies. A recording medium on which the program according to any one of claims 13 to 23 is recorded.

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