JP6925075B1 - Robot waiting method, robot and computer readable storage medium - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a robot waiting method, a robot and a computer-readable storage medium capable of effectively increasing the picking efficiency of the robot. The present application provides a robot waiting method, a robot and a computer-readable storage medium. In this method, the waiting method is applied to the robot, and when it is detected that the robot has reached the waiting area corresponding to the target point, the traveling mode is switched to the waiting mode and whether the target point is occupied. Detecting whether or not, and if the target point is not occupied, move forward along the waiting area in the waiting mode to reach the target point, and occupy the target point, and the target point is already occupied. When occupied, it includes advancing along the waiting area while keeping the preset distance range with the adjacent robot in front in the waiting mode. [Selection diagram] Fig. 1

Description

The present application relates to the field of robot technology, particularly to robot waiting methods in storage warehouse systems, robots and computer readable storage media.

In a large warehouse, various products being ordered are stored in each area of the warehouse and are mixed with a large amount of other products. If the picking staff alone picks the products being ordered, the picking staff will be long. There is a problem that the picking efficiency is lowered due to the long working hours of the picking staff because they have to walk a long distance.

If a robot is used instead of walking by the picking staff to improve picking efficiency, the robot will move between areas of the warehouse, and the picking staff will simply take the goods from the display shelves and place them in the return box on the robot. It is possible to pick the product in the product order by the cooperation of the human machine.

When multiple robots perform picking of goods orders in a warehouse, there is a competition for resources. That is, a situation occurs in which a plurality of robots head toward the same target point at the same time, and as a result, the robots are congested in some areas and there are no robots in other areas. If a plurality of robots are directed to the same target point in order, the picking time of the product order becomes long, which eventually leads to a decrease in picking efficiency.

In the embodiment of the present application, by providing a waiting area near the target point, the waiting time when the robots compete for the same target point can be reduced, and the picking efficiency can be effectively improved. A waiting method, a robot and a computer-readable storage medium are provided.

In the first direction, the following robot waiting method is provided. The method is a waiting method applied to a robot, in a traveling mode in the order in which the robot receives the position information of a target point transmitted from a server and the position information of a waiting area corresponding to the target point. Go to the waiting area, when detecting the arrival to the waiting area, and to switch the drive mode to the waiting mode, and that the target point is detected whether it is occupied, if When the target point is not occupied, in the waiting mode, the target point is advanced along the waiting area to reach the target point, and the target point is occupied, and the target point is already occupied. If so, the speed of the robot in the waiting mode includes the advance along the waiting area while keeping the preset distance range with the adjacent robot in front in the waiting mode. It is less than the speed of the robot in the traveling mode.

In the second direction, the following robots are provided. The robot moves to the waiting area in the traveling mode in the order of receiving the position information of the target point and the position information of the waiting area corresponding to the target point transmitted from the server, and reaches the waiting area. when it is detected that, switches the drive mode to the waiting mode, the a process module for the target point is detected whether it is occupied, based on the detection result of the processing module, wherein the target point is occupied When not, in the waiting mode, advance along the waiting area to reach the target point, and occupy the target point, and when the target point is already occupied, in the waiting mode. The processing module includes the adjacent robot in front and an execution module for advancing along the waiting area while keeping a preset distance range, and the processing module determines the speed of the robot in the waiting mode. It is set to be less than the speed of the robot in the traveling mode.

In the third direction, the following robots will be provided. The robot includes a processor, a communication interface, a memory and a communication bus, the processor, the communication interface and the memory can communicate with each other by the bus, and the memory is for storing a computer program, and the processor. Is for executing the program stored in the memory to realize the method of waiting for the robot's turn described on the first surface.

In the fourth direction, the following computer-readable storage medium is provided. A computer program is stored in the computer-readable storage medium, and when the computer program is executed by the processor, the robot turn-waiting method described on the first surface is realized.

When it is detected that the robot has reached the waiting area corresponding to the target point based on the waiting method of the robot, the robot and the computer-readable storage medium provided by the embodiment of the present application, the traveling mode is changed to the waiting mode. Switch to detect if the target point is occupied, and if the target point is not occupied, move forward along the waiting area in the waiting mode to reach the target point, and then occupy the target point. If the target point is already occupied, it advances along the waiting area while keeping the preset distance range with the adjacent robot in front in the waiting mode. As a result, by using the waiting area provided based on the area where congestion occurs, the robot waits in the waiting area before reaching the target point, passes through the waiting area, and reaches the target point in order. This makes it possible to reduce the amount of time the robot waits when competing for the same target point, and effectively improve the efficiency of picking.

In order to more clearly explain one or more embodiments of the present application or prior art approaches in the prior art, the drawings used in the description of the examples or prior art will be briefly introduced below. It goes without saying that the drawings in the following description are merely some of the examples described in this application, and those skilled in the art can obtain yet other drawings based on these drawings without creative labor. ..

FIG. 1 is a schematic flow diagram of a method for realizing one of the robot turn-waiting methods according to the embodiment of the present application. FIG. 2 is a schematic flow diagram of a method for realizing one of the waiting modes of the embodiment of the present application. FIG. 3 is a schematic flow diagram of another implementation method of the robot turn waiting method according to the embodiment of the present application. FIG. 4 is a schematic flow diagram of another implementation method of the robot turn-waiting method according to the embodiment of the present application. FIG. 5A is a schematic view of a waiting area provided in the warehouse of the embodiment of the present application. FIG. 5B is a schematic diagram illustrating that the robot according to the present application waits in the waiting area. FIG. 6 is a schematic diagram of the configuration structure of the robot according to the embodiment of the present application. FIG. 7 is a schematic diagram of another configuration structure of the robot according to the embodiment of the present application.

One of the present applications, together with the drawings in one or more embodiments of the present application, so that those skilled in the art can better understand the technical scheme in one or more embodiments of the present application. Alternatively, the technical schemes in the plurality of embodiments will be clearly and completely described. Of course, the examples described are not all examples of the present invention, but only some examples. Based on one or more embodiments of the invention, all other embodiments obtained by those skilled in the art without creative labor also fall within the scope of the invention.

FIG. 1 is a schematic flow diagram of a method for realizing one of the robot turn-waiting methods according to the embodiment of the present application. The waiting method shown in FIG. 1 is applied to a robot, which can be executed by the robot, and the robot can be a robot in a storage warehouse system. For example, a product being ordered by going back and forth between each area of the warehouse. However, the examples of the present application are not limited to the type of robot. As shown in FIG. 1, the waiting method includes at least the following steps.

S102, when it is detected that the robot has reached the waiting area corresponding to the target point, the traveling mode is switched to the waiting mode.

In the embodiment of the present application, the target point can be an area where resource competition exists when the robot picks up a product order in the warehouse. For example, a scan point for performing a scan operation in a storage warehouse system and a packing operation The packing points to be performed are areas where congestion is likely to occur, but the examples of the present application do not limit the type of target points. A waiting area is provided near the target point, and the robot heading for the target point can reach the waiting area first, wait in turn, and then reach the target point from the waiting area. Arbitrarily, one waiting area may be provided at each target point, or one waiting area may be provided at a plurality of target points, but the embodiment of the present application does not limit the setting form of the waiting area. ..

In the embodiment of the present application, the robot can include two types of motion modes, a traveling mode and a waiting mode, and the robot exercises the non-order waiting area in the traveling mode and the waiting area in the waiting mode. The robot moves from the initial position to the waiting area corresponding to the target point in the running mode, and when it reaches the waiting area corresponding to the target point, the running mode is switched to the waiting mode, and in the waiting area in the waiting mode. When exercising, reaching the target point, and leaving the target point, the waiting mode is switched to the running mode. The embodiment of the present application is not limited to the implementation method of the running mode and the waiting mode.

S104, Detects whether or not the target point is occupied.

If the target point is not occupied, S106 is executed, and if the target point is already occupied, S108 is executed.

S106, in the waiting mode, move forward along the waiting area to reach the target point, and occupy the target point.

S108, in the waiting mode, the robot advances along the waiting area while keeping the preset distance range with the adjacent robot in front.

In the embodiment of the present application, the robot can adopt different motion modes in the waiting area by detecting the state of the target point in the waiting mode. Among them, the state of the target point can include a state in which the target point is already occupied by another robot and a state in which the target point is not occupied by another robot. The motion form that the robot can adopt in the waiting area can include a form in which the robot voluntarily moves and a form in which the robot follows and moves. When there is no other robot in front of the robot, the robot adopts a form of voluntary movement, moves forward along the waiting area, and when there is another robot in front of the robot, the robot follows. Adopting a form of movement, it moves forward along the waiting area while keeping the preset distance range with the adjacent robot in front.

Optionally, the robot can move at a predetermined speed in the waiting area, and the predetermined speed can be less than the speed in the running mode of the robot.

In some optional examples, when the first robot reaches the waiting area corresponding to the target point, the running mode of the first robot is switched to the waiting mode, and whether or not the target point is occupied. By detecting, it is confirmed that the target point is not occupied, and then, in the waiting mode, the target point is advanced along the waiting area to reach the target point, and the target point is occupied. When the second robot reaches the waiting area corresponding to the target point, the target point is already set by switching the running mode of the second robot to the waiting mode and detecting whether or not the target point is occupied. After confirming that it is occupied, it advances along the waiting area while keeping the preset distance range with the first robot in the waiting mode. When the third robot reaches the waiting area corresponding to the target point, the target point is already set by switching the running mode of the third robot to the waiting mode and detecting whether or not the target point is occupied. After confirming that it is occupied, it advances along the waiting area while keeping the preset distance range with the second robot in the waiting mode. When the first robot stops at the target point because the target point is occupied, the second robot stops at the first queuing place in the waiting area, which is separated from the target point by a preset distance range. The third robot can stop at the second queuing area, which is separated from the first queuing area by the preset distance range in the waiting area, and so on. When the first robot leaves the target point, the waiting mode is switched to the running mode. The second robot located in the first queue in the waiting area determines whether the target point is occupied by detecting whether or not the target point is occupied, and waits in line from the first queue. In mode, move forward along the waiting area to reach the target point, and occupy the target point, and the third robot located in the second queue in the waiting area determines whether the target point is occupied or not. By detecting, it is confirmed that the target point is already occupied, and the target point is advanced from the second queue along the waiting area in the waiting mode to reach the first queuing place, and so on. , The advance to follow the order of the robots in the waiting area is completed.

When it is detected that the robot has reached the waiting area corresponding to the target point based on the robot waiting method provided by the embodiment of the present application, the traveling mode is switched to the waiting mode and the target point is occupied. Detects whether or not, and if the target point is not occupied, it advances along the waiting area in the waiting mode to reach the target point, and then occupies the target point, if the target point is already occupied. If so, it advances along the waiting area while keeping the preset distance range with the adjacent robot in front in the waiting mode. As a result, using the waiting area provided based on the area where congestion occurs, the robot waits in the waiting area before reaching the target point, and reaches the target point in order according to the waiting area. The time to wait when the robot competes for the same target point can be reduced, and the picking efficiency can be effectively improved.

The method of waiting for the robots in the present application will be described in detail below together with the examples of FIGS. 2 to 4.

FIG. 2 is a schematic flow diagram of a method for realizing one of the waiting modes of the embodiment of the present application. As shown in FIG. 2, advancing along the waiting area in the waiting mode includes at least the following steps.

S202, the feature of the forward object is detected.

In the examples of the present application, the robot can detect the characteristics of the front object by a radar or another sensor, and for example, a laser radar or the like can be adopted. There is no limitation on the implementation method to be detected.

S204, based on the characteristics of the front object, it is determined whether or not the front object is a robot, and if the front object is a robot, S206 is executed, and if the front object is not a robot, S208 is executed.

S206, following the forward robot along the waiting area, moves forward.

S208, stop moving forward along the waiting area.

In the embodiments of the present application, the robot detects the characteristics of the front object in the waiting mode to determine whether the front object is a robot or an obstacle that is not a robot, and the front object is a robot and an obstacle. When it is determined that, a different processing method can be adopted. When determining that the front object is a robot based on the characteristics of the front object, the robot follows the front robot along the waiting area and moves forward, and based on the characteristics of the front object, the front object is an obstacle. At the time of determination, the robot stops moving forward along the waiting area, and if it can detect that there is no obstacle in front, it moves forward along the waiting area.

In this embodiment, the robot can distinguish whether the front object is an obstacle or another robot by detecting the feature of the front object in the waiting mode and identifying the front object. Therefore, in the process of the robot moving forward along the waiting area, different processing methods are adopted depending on the obstacle in front or other robots to ensure the safety and effectiveness when the robot moves in the waiting area. can do.

FIG. 3 is a schematic flow diagram of another implementation method of the robot turn waiting method according to the embodiment of the present application. As shown in FIG. 3, the waiting method includes at least the following steps.

S302, the position information of the target point, the position information of the corresponding waiting entrance point, and the position information of other robots in the warehouse are acquired.

In the embodiment of the present application, the waiting area may include a waiting entrance point, and the waiting area may be a rectangular area specified with the waiting entrance point and the target point as boundary points. The example is not limited to the realization method of the waiting area. Optionally, the robot can receive the position information of the target point, the position information of the corresponding turn waiting entry point, and the position information of other robots in the warehouse transmitted by the server. Alternatively, the robot can also send to the server an application for acquiring the position information of the target point, the position information of the corresponding turn-by-entry point, and the position information of another robot. The embodiment of the present application does not limit the acquisition method of the position information of the target point, the position information of the corresponding turn waiting entrance point, and the position information of other robots.

Based on the position information of the turn waiting entrance point in S304, it is detected whether or not the robot has reached the turn waiting area corresponding to the target point.

S306, when it is detected that the robot has reached the waiting area corresponding to the target point, the traveling mode is switched to the waiting mode.

In the embodiment of the present application, the robot matches the detected current position information with the position information of the turn waiting entrance point corresponding to the target point acquired from the server, and whether or not the robot has reached the turn waiting area corresponding to the target point. For example, by matching the two with coordinates in the same coordinate system, it is possible to determine whether or not the robot has reached the waiting area corresponding to the target point. The embodiment of the present application does not limit the realization method for detecting whether or not the robot has reached the waiting area corresponding to the target point.

Based on S308, the position information of the target point and the position information of other robots in the warehouse, it is detected whether or not the target point is occupied.

In the embodiment of the present application, the robot can match the position information of the target point acquired from the server with the position information of another robot in the warehouse, and can determine whether or not the target point is occupied. For example, both. By matching the coordinates with the coordinates in the same coordinate system, it is possible to determine whether or not the target point is occupied. The embodiment of the present application does not limit the realization method for detecting whether or not the target point is occupied.

If the target point is not occupied, S310 is executed, and if the target point is already occupied, S312 is executed.

S310, in the waiting mode, advances along the waiting area to reach the target point, and occupies the target point.

S312, in the waiting mode, moves forward along the waiting area while keeping the preset distance range with the adjacent robot in front.

In this embodiment, the description of S310 and S312 will not be repeated here because the description of S106 and S108 of FIG. 1 can be referred to.

In this embodiment, a waiting entry point is provided in the waiting area, and the waiting area is determined based on the waiting entrance point and the target point to determine the waiting area and whether the robot has reached the waiting area. Detection can be done easily. In this embodiment, by acquiring the position information of other robots in the warehouse and the position information of the target point, it is possible to easily detect whether or not the target point is occupied. Based on this, the motion form in the waiting area of the robot can be determined.

FIG. 4 is a schematic flow diagram of another implementation method of the robot turn-waiting method according to the embodiment of the present application. In this embodiment, the target points are the scan point and the packing point, and as shown in FIG. 4, the waiting method includes at least the following steps.

S402, the position information of the scan point and the position information of the corresponding turn waiting entry point are received.

In the embodiment of the present application, as shown in FIG. 5A, FIG. 5A is a schematic view of a waiting area provided in the warehouse of the embodiment of the present application. After the experiment, it can be determined that the area where the robot is congested is the scan point 123 for performing the scanning operation and the packing point 125 for performing the packing operation in the warehouse. A waiting area 122 can be provided. The waiting area 122 is a rectangular area and includes the waiting entrance points 121 and 124, and the waiting area 122 is a straight line between the waiting entrance point 121 and the scanning point 123, and the waiting entrance point 124 and the packing point 125, respectively. It is assumed that the waiting entrance point 121 and the scanning point 123 are the boundary points of the waiting area 122, and the waiting entrance point 124 and the packing point 125 are the boundary points of the waiting area 122. Can be done. Since the turn waiting entrance point 121 and the scan point 123 have a one-to-one correspondence relationship, and the turn waiting entrance point 124 and the packing point 125 have a one-to-one correspondence relationship, the turn waiting entrance point 121 is linked to the scan point 123. Then, the waiting entrance point 124 can be associated with the packing point 125.

S404, route planning is performed based on the position information of the turn waiting entrance point, and the turn waiting area corresponding to the scan point is reached based on the planned route.

In the embodiment of the present application, the robot receives the position information of the scan point 123 and the position information of the corresponding turn waiting entrance point 121 transmitted by the server, then performs route planning based on the position information of the turn waiting entrance point 121, and then performs route planning. Based on the planned route, the waiting area corresponding to the scan point 123 is reached from the current position. Optionally, the current position of the robot may be the parking area 126, the charging area 127, or any other position in the warehouse, and the embodiments of the present application are not limited in this regard.

S406, the running mode is switched to the waiting mode, the waiting area is entered, and the waiting area is advanced along the waiting area.

In the embodiment of the present application, when a plurality of robots sequentially receive the position information of the same scan point 123 and the position information of the corresponding turn waiting entrance points 121 transmitted by the server, the plurality of robots sequentially in the traveling mode. The turn waiting entrance point 121 is reached, the running mode is switched to the turn waiting mode, the turn waiting area 122 is entered from the turn waiting entrance point 121, and the scan point 123 is reached along the turn waiting area 122 in the turn waiting mode. Advance to. As shown in FIG. 5B, FIG. 5B is a schematic diagram illustrating that the robots of the present application embodiment wait in turn in the waiting area. Among them, the first robot enters the waiting area 122 from the waiting entrance point 121, then advances along the waiting area 122 in the waiting mode, reaches the scanning point 123, and stops at the scanning point 123. After entering the waiting area 122 from the waiting entrance point 121, the second robot follows the first robot in the waiting mode and moves forward along the waiting area 122, and the first robot reaches the scanning point 123. When stopped, the second robot stops at the first queue, which is a preset distance away from the scan point 123, and the third robot enters the waiting area 122 from the waiting entrance point 121, and then waits in the waiting mode. Follows the second robot and moves forward along the waiting area 122, and when the second robot stops at the first queue, the third robot is separated from the first queue by a preset distance. Stop at the second queue and repeat the same procedure. After the first robot leaves scan point 123, the second robot reaches scan point 123 in queue mode, then stops at scan point 123, and the third robot reaches the first queue in queue mode. Then stop at the first queue and repeat the same. In this way, the robot completes the process of waiting in the waiting area 122.

S408, occupy the scan point and display the scan information.

In the embodiment of the present application, the robot that reaches the scan point 123 and occupies the scan point 123 receives the product order sent by the server at the scan point 123, and the robot is the mobile terminal installed based on the product order. Displays scan information in, which informs the work staff to perform the scan operation.

S410, when leaving the scan point, the waiting mode is switched to the running mode.

In the embodiment of the present application, when the robot occupying the scan point 123 leaves the scan point 123 after the scan is completed, the waiting mode is switched to the traveling mode, and after the scanning point 123 is released, the robot is lined up in the corresponding waiting area 122. The robot occupies the scan point 123 in order.

S412, the position information of the packing point and the position information of the corresponding turn waiting entrance point are received.

In the embodiment of the present application, the robot picks the product for which the product is being ordered and then packs the product toward the packing point 125. At this time, the robot uses the position information of the packing point 125 transmitted by the server and the corresponding turn waiting entrance point 124. Receive location information.

S414, route planning is performed based on the position information of the turn waiting entrance point, and the turn waiting area corresponding to the packing point is reached based on the planned route.

In the embodiment of the present application, the robot receives the position information of the packing point 125 and the position information of the corresponding waiting entrance point 124 transmitted by the server, and then performs route planning based on the position information of the waiting entrance point 124 for planning. Reach the waiting area corresponding to packing point 125 from the current position based on the route.

S416, the traveling mode is switched to the waiting mode, the waiting area is entered, and the vehicle advances along the waiting area in the waiting mode.

In the embodiment of the present application, when a plurality of robots receive the position information of the same packing point 125 and the position information of the corresponding turn waiting entrance points 124 sequentially transmitted by the server, the plurality of robots wait in order in the traveling mode. Reach the entrance point 124, then switch the driving mode to the waiting mode, enter the waiting area 122 from the waiting entrance point 124, and move forward along the waiting area 122 in the waiting mode until the packing point 125 is reached. do. Among them, the first robot enters the waiting area 122 from the waiting entrance point 124, then advances along the waiting area 122 in the waiting mode until it reaches the packing point 125, and stops at the packing point 125. After entering the waiting area 122 from the waiting entrance point 124, the second robot follows the first robot in the waiting mode and moves forward along the waiting area 122, and the first robot moves forward along the waiting area 122. When stopped at, the second robot stops at the first queue, which is a preset distance away from the packing point 125, and the third robot enters the waiting area 122 from the waiting entrance point 124, and then waits in the waiting mode. Follows the second robot and moves forward along the waiting area 122, and when the second robot stops at the first queue, the third robot is separated from the first queue by a preset distance. After stopping at the second queue and repeating the same procedure, the second robot reaches the packing point 125 in the waiting mode, stops at the packing point 125, and then stops at the packing point 125, and the third robot leaves the packing point 125. The robot reaches the first queue in the waiting mode, stops at the first queue, and so on. In this way, the process in which the robot waits in the waiting area 122 is completed.

S418, occupy the packing point, and display the packing screen.

In the embodiment of the present application, the robot that reaches the packing point 125 and occupies the packing point 125 asks the work staff to perform the packing operation by displaying the packing screen on the attached mobile terminal at the packing point 125. Inform.

S420, When leaving the packing point, the waiting mode is switched to the running mode.

In the embodiment of the present application, when the robot occupying the packing point 125 leaves the packing point 125 after the work staff confirms the end of packing, the waiting mode is switched to the running mode, and after the packing point 125 is released, the corresponding robot is used. Robots lined up in the waiting area 122 occupy the packing point 125 in order.

In this embodiment, the scan points and packing points that are likely to be congested in the order processing process are determined, and a waiting area is provided, whereby the robot waits in the waiting area before reaching the scanning points and packing points. Robots can remain in motion during the order processing process, where they can, reduce the amount of time they wait when competing for the same resources, and ensure that there is sufficient waiting area space. , The efficiency of picking can be effectively increased.

Based on the same technical concept, the embodiments of the present application further provide robots corresponding to the robot waiting method described above. The robot can be a robot in a storage warehouse system, for example, a robot that can move between areas of a warehouse and load products for which a product is being ordered. Without limitation, FIG. 6 is a schematic diagram of the configuration structure of the robot according to the embodiment of the present application. The robot executes the robot turn-waiting method described in FIG. 1, and as shown in FIG. 6, the robot includes at least a processing module 610 and an execution module 620, of which the processing module 610 is the execution module 620. Is connected with.

The processing module 610 switches the traveling mode to the waiting mode when it detects that the robot has reached the waiting area corresponding to the target point, and detects whether or not the target point is occupied. be.

Based on the detection result of the processing module 610, the execution module 620 advances along the waiting area in the waiting mode to reach the target point when the target point is not occupied, and then occupies the target point and targets. This is for moving forward along the waiting area while keeping the preset distance range with the adjacent robot in front in the waiting mode when the point is already occupied.

In this embodiment, the description of the processing module 610 can be referred to the description of S102 and S104 of FIG. 1, and therefore will not be repeated here.

In this embodiment, the description of the execution module 620 can be referred to the description of S106 and S108 of FIG. 1, and therefore will not be repeated here.

Based on the robot provided by the embodiment of the present application, when it is detected that the robot has reached the waiting area corresponding to the target point, the traveling mode is switched to the waiting mode and it is detected whether or not the target point is occupied. If the target point is not occupied, move forward along the waiting area in the waiting mode to reach the target point, and occupy the target point, if the target point is already occupied, the turn In wait mode, move forward along the waiting area while keeping the preset distance range with the adjacent robot in front. As a result, using the waiting area provided based on the area where congestion occurs, the robot waits in the waiting area before reaching the target point, and reaches the target point in order according to the waiting area. The time to wait when the robot competes for the same target point can be reduced, and the picking efficiency can be effectively improved.

Optionally, the processing module 610 further detects the characteristics of the front object and determines whether or not the front object is a robot based on the characteristics of the front object.

Based on the judgment result of the processing module 610, the execution module 620 further advances following the forward robot along the waiting area when the front object is a robot, and moves forward in the waiting area when the front object is not a robot. Stop moving forward along.

Optionally, the waiting area includes a waiting entrance point, and the waiting area is a rectangular area specified with the waiting entrance point and the target point as boundary points.

Optionally, as shown in FIG. 7, the robot further includes a communication module 630, which is connected to the processing module 610 to acquire the position information of the target point and the position information of the corresponding turn waiting entry point. Is for.

The processing module 610 is for detecting whether or not the robot has reached the waiting area corresponding to the target point based on the position information of the waiting entrance point.

Optionally, the communication module 630 is further for acquiring location information of other robots in the warehouse.

The processing module 610 is for detecting whether or not the target point is occupied based on the position information of the target point and the position information of other robots in the warehouse.

Optionally, the processing module 610 further switches the waiting mode to the traveling mode when the robot leaves the target point.

Optionally, the target points include scan points for performing scan operations and / or packing points for performing packing operations when picking goods orders in the warehouse.

Based on the same technical concept, the embodiments of the present application further provide robots corresponding to the robot waiting method described above. The robot includes a processor, a communication interface, a memory and a communication bus, of which the processor, the communication interface and the memory are communicated with each other by the bus, the memory is for storing a computer program, and the processor is stored in the memory. It is for executing the program, and the following flow is realized.

When it is detected that the robot has reached the waiting area corresponding to the target point, the traveling mode is switched to the waiting mode, it is detected whether or not the target point is occupied, and if the target point is occupied, the target point is occupied. If not, in the waiting mode, advance along the waiting area to reach the target point, and occupy the target point, and if the target point is already occupied, in the waiting mode. It advances along the waiting area while keeping the reset distance range with the adjacent robot in front.
Based on the robot provided by the embodiment of the present application, when it is detected that the robot has reached the waiting area corresponding to the target point, the traveling mode is switched to the waiting mode and it is detected whether or not the target point is occupied. If the target point is not occupied, move forward along the waiting area in the waiting mode to reach the target point and occupy the target point, if the target point is already occupied, the turn In wait mode, move forward along the waiting area while keeping the preset distance range with the adjacent robot in front. As a result, using the waiting area provided based on the area where congestion occurs, the robot waits in the waiting area before reaching the target point, and reaches the target point in order according to the waiting area. The time to wait when the robot competes for the same target point can be reduced, and the picking efficiency can be effectively improved.

Corresponding to the detection method described above, based on the same technical concept, the embodiments of the present application further provide a computer-readable storage medium. The computer-readable storage medium is for storing computer-executable commands, and the computer-executable commands realize the following flow at the time of execution.

When it is detected that the robot has reached the waiting area corresponding to the target point, the traveling mode is switched to the waiting mode, it is detected whether or not the target point is occupied, and if the target point is occupied, the target point is occupied. If not, in the waiting mode, advance along the waiting area to reach the target point, and occupy the target point, and if the target point is already occupied, in the waiting mode. It advances along the waiting area while keeping a preset distance range with the adjacent robot in front.

When it is detected that the robot has reached the waiting area corresponding to the target point based on the computer-readable storage medium provided by the embodiment of the present application, the traveling mode is switched to the waiting mode and the target point is occupied. Detects whether or not, and if the target point is not occupied, move forward along the waiting area in the waiting mode to reach the target point and occupy the target point, if the target point is already occupied If so, the robot advances along the waiting area while keeping the preset distance range with the adjacent robot in front in the waiting mode. As a result, using the waiting area provided based on the area where congestion occurs, the robot waits in the waiting area before reaching the target point, and reaches the target point in order according to the waiting area. The time to wait when the robot competes for the same target point can be reduced, and the picking efficiency can be effectively improved.

It should be noted that the terms "provide", "include" or any other alternative term mean to cover non-exclusive inclusion, so a process, method, commodity or device containing a set of elements may be these elements alone. It includes other elements that are not explicitly mentioned, or that are specific to these processes, methods, goods or devices. In the absence of more restrictions, an element limited by the term "contains one ..." does not preclude the existence of another same element in a process, method, commodity or device that includes said element.

One or more embodiments of the present application can be described in the general context of computer-executable commands executed by a computer. For example, a program module. In general, a program module includes routines, programs, objects, assemblies, data structures, etc. that perform a particular task or realize a particular abstract data type. In addition, one or more embodiments of the present application may be practiced in a distributed computing environment, and in these distributed computing environments, tasks can be executed by a remote processing device connected by a communication network. In a distributed computing environment, program modules can be located on local and remote computer storage media, including storage devices.

Each of the examples in the present application is described by the cumulative method, and the same similar parts may be referred to each other among the examples, and the emphasis on each example is the same as that of the other examples. It's a different part. In particular, as for the system embodiment, since the basics are similar to the method embodiment, the explanation is relatively simple, and the related parts may refer to the partial explanation of the method embodiment.

The above contents are not for limiting the present application, but merely for examples of the present application. For those skilled in the art, this application may have various modifications and variations. Any amendments, equal replacements, improvements, etc. made within the ideas and principles of the present application are all within the scope of the claims of the present application.

Claims (10)

It is a waiting method applied to robots,
The robot moves to the waiting area in the traveling mode in the order of receiving the position information of the target point and the position information of the waiting area corresponding to the target point transmitted from the server, and reaches the waiting area. when it is detected that a switching of the drive mode to the waiting mode,
Detecting whether or not the target point is occupied and
If the target point is not occupied, the target point is moved forward along the waiting area in the waiting mode to reach the target point, and the target point is occupied.
If the target point is already occupied, it includes moving forward along the waiting area while keeping a preset distance range with the adjacent robot in front in the waiting mode.
The speed of the robot in the waiting mode is less than the speed of the robot in the traveling mode.
A method of waiting for a robot to take turns. Moving forward along the waiting area in the waiting mode
Detecting the characteristics of the object in front and
Judging whether or not the front object is a robot based on the characteristics of the front object,
If the forward object is a robot, it follows the front robot and moves forward along the waiting area.
If the forward object is not a robot, it includes stopping advancing along the waiting area.
The method of waiting for a robot in order according to claim 1. The waiting area includes a waiting entrance point, and the waiting area is a rectangular area specified with the waiting entrance point and the target point as boundary points.
The method of waiting for a robot in order according to claim 1. When the robot detects that it has reached the waiting area, before switching the drive mode to the waiting mode,
Moreover,
Acquiring the position information of the target point and the position information of the corresponding waiting entrance point,
Includes detecting whether or not the robot has reached the waiting area corresponding to the target point based on the position information of the waiting entrance point.
The method of waiting for a robot in order according to claim 3. Before detecting whether or not the target point is occupied,
Moreover,
Including acquiring the position information of other robots in the warehouse
Detecting whether or not the target point is occupied is
Includes detecting whether or not the target point is occupied based on the position information of the target point and the position information of another robot in the warehouse.
The method of waiting for a robot in order according to claim 4. Moreover,
The robot includes switching the waiting mode to the traveling mode when the robot leaves the target point.
The method of waiting for a robot in order according to any one of claims 1 to 5, wherein the robot's turn wait method. The target point includes a scan point for performing a scan operation and / or a packing point for performing a packing operation when picking a product order in a warehouse.
The method of waiting for a robot in order according to claim 6. The robot moves to the waiting area in the traveling mode in the order of receiving the position information of the target point and the position information of the waiting area corresponding to the target point transmitted from the server, and reaches the waiting area. When the above is detected, the traveling mode is switched to the waiting mode, and a processing module for detecting whether or not the target point is occupied, and a processing module.
Based on the detection result of the processing module, when the target point is not occupied, the target point is advanced along the waiting area in the waiting mode to reach the target point, and the target point is occupied. When the target point is already occupied, the execution module for advancing along the waiting area while keeping the preset distance range with the adjacent robot in front in the waiting mode,
Including
The processing module sets the speed of the robot in the waiting mode to be less than the speed of the robot in the traveling mode.
A robot characterized by that. Includes processor, communication interface, memory and communication bus
The processor, the communication interface and the memory can communicate with each other by a bus.
The memory is for storing a computer program and
The processor executes a program stored in the memory to realize the robot turn-waiting method according to any one of claims 1 to 7.
A robot characterized by that. The computer program is stored
The method of waiting for a robot according to any one of claims 1 to 7 is realized when the computer program is executed by a processor.
A computer-readable storage medium characterized by that.

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