JP2018188308A - Picking facility - Google Patents

Abstract

PROBLEM TO BE SOLVED: To shorten a work period of loading articles onto a single container, in a picking facility for transferring articles stored in an article storage body to the container by a picking robot.SOLUTION: A picking facility 1 for transferring articles stored in a case X to a container Y by a picking robot 5b comprises a travelable robot carriage 5 on which the picking robot 5b is mounted, and a container carriage 6, capable of traveling while separating from the robot carriage 5, on which the container Y can be mounted.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a picking facility.

  2. Description of the Related Art In logistics facilities that handle a wide variety of goods, a picking operation is performed in which goods are transferred from a case containing the same kind of goods to a container prepared for each delivery destination. In recent years, picking work is being automated by using a picking robot in order to reduce work by an operator. For example, Patent Document 1 discloses an apparatus that allows a container to be placed on a cart on which a picking robot is mounted, and reloads articles by the picking robot on the container placed on the cart while the cart is running. Has been.

JP 2014-231420 A

  However, when the container can be placed on the carriage on which the robot is mounted as in Patent Document 1, the container delivery operation cannot be performed while the robot is performing the picking operation. Conversely, the robot cannot perform the picking operation while the container is being delivered. In addition, when a camera is installed on a cart and the type and posture of an article are detected from the image data of the camera, the container delivery operation cannot be performed even during image capture or image data processing. Thus, with the configuration disclosed in Patent Document 1, picking work or the like cannot be performed during the delivery work of the container to the carriage, and the time required for loading the article into one container increases. Become.

  The present invention has been made in view of the above-described problems, and in a picking facility for transferring an article accommodated in an article container by a picking robot to the container, shortening an article loading operation period for one container. With the goal.

  The present invention adopts the following configuration as means for solving the above-described problems.

  1st invention is the picking equipment which transfers the articles | goods accommodated in the article container by the picking robot to a container, Comprising: The robot cart with which the said picking robot is mounted and which can be traveled, and the said container can be mounted In addition, a configuration is adopted in which a container carriage that can travel separately from the robot carriage is provided.

  A second invention includes a recognition unit that is installed in the robot carriage and recognizes an article stored in the article container in the first invention, and the recognition unit recognizes the article. A configuration is adopted in which a container cart control unit that moves the container by moving the container cart separately from the robot cart is adopted.

  According to a third invention, in the first or second invention, the container cart includes a transfer device for transferring the container.

  According to a fourth invention, in any one of the first to third inventions, the robot includes a rack on which the article container is placed and a rail laid along the rack, the robot carriage and the container carriage. Is configured to be able to travel along the same rail.

  According to a fifth invention, in any one of the first to third inventions, a rack on which the article container is placed, a first rail that is laid along the rack and on which the robot carriage travels, A configuration is adopted in which a second rail is provided that is parallel to the first rail and is laid on the opposite side of the rack with respect to the first rail and on which the container carriage travels.

  According to a sixth invention, in any one of the first to fifth inventions, when the robot carriage is moved to another location, the container carriage is moved in synchronization with the robot carriage, and the picking robot A configuration is adopted in which an article can be transferred to the container carriage.

  7th invention employ | adopts the structure provided with two or more said container trolley | bogie in any of the said 1st-6th invention.

  According to an eighth aspect of the present invention, in the first aspect of the present invention, a configuration is adopted in which a recognition unit carriage that has a recognition unit that recognizes an article accommodated in the article container and that can travel is provided separately from the robot carriage.

  According to a ninth invention, in the eighth invention, a container cart control unit that moves the container by moving the container cart separately from the robot cart while the recognition unit recognizes the article. A configuration of providing is adopted.

  A tenth aspect of the present invention employs a configuration in which the recognition unit carriage is suspended and supported above the robot carriage in the eighth or ninth aspect.

  The present invention includes a container cart that can travel separately from a robot cart on which a picking robot is mounted. For this reason, the operation | work which delivers a container with respect to a container trolley | bogie and the operation | work by a robot trolley | bogie can be performed in parallel. Therefore, according to the present invention, it is possible to shorten the loading operation period of an article into one container in a picking facility that transfers an article accommodated in an article container by a picking robot.

It is a top view showing typically a schematic structure of picking equipment in one embodiment of the present invention. It is a functional block diagram which shows schematic structure of the picking installation in one Embodiment of this invention. It is a flowchart for demonstrating operation | movement of the ground control part with which the picking installation in one Embodiment of this invention is provided. It is a flowchart for demonstrating operation | movement of the general control part with which the picking installation in one Embodiment of this invention is provided. It is a flowchart for demonstrating operation | movement of the traveling control part with which the picking installation in one Embodiment of this invention is provided. It is a flowchart for demonstrating operation | movement of the article | item discrimination | determination control processing part with which the picking installation in one Embodiment of this invention is provided. It is a flowchart for demonstrating operation | movement of the container trolley | bogie control part with which the picking installation in one Embodiment of this invention is provided. It is a schematic diagram for demonstrating operation | movement with the robot trolley | bogie and container trolley with which the picking installation in one Embodiment of this invention is provided. It is a schematic diagram for demonstrating operation | movement with the robot trolley | bogie and container trolley with which the picking installation in one Embodiment of this invention is provided. It is a top view which shows typically schematic structure of the modification of the picking installation in one Embodiment of this invention. It is a top view which shows typically schematic structure of the picking equipment in 2nd Embodiment of this invention. It is a functional block diagram which shows schematic structure of the picking equipment in 2nd Embodiment of this invention. It is a flowchart for demonstrating operation | movement of the picking installation in 2nd Embodiment of this invention.

  Hereinafter, an embodiment of a picking facility according to the present invention will be described with reference to the drawings. In the following drawings, the scale of each member is appropriately changed in order to make each member a recognizable size.

  FIG. 1 is a plan view schematically showing a schematic configuration of a picking facility 1 of the present embodiment. As shown in FIG. 1, FIG. 2 is a functional block diagram showing a schematic configuration of the picking facility 1 of the present embodiment. As shown in FIG. 1, the picking facility 1 according to the present embodiment includes a rail 2 laid on a floor surface and a flow rack 3 (rack) disposed along the rail 2. Further, the picking facility 1 of the present embodiment includes a ground system 4, a robot cart 5, and a container cart 6.

  As shown in FIG. 1, the rail 2 is laid in a straight line, and a robot carriage 5 and a container carriage 6 are placed so as to be able to travel. The rail 2 guides the traveling robot cart 5 and container cart 6 in a straight line. The flow rack 3 is a shelf on which a case X (article container) supplied from the outside (for example, an automatic warehouse (not shown)) is placed, and is installed on each side of the rail 2. These flow racks 3 are sized so that a plurality of cases X can be placed along the rails 2. Further, these flow racks 3 are arranged close to the rail 2 so that a picking robot 5b (to be described later) of the robot cart 5 that travels along the rail 2 is disposed at a distance accessible to the inside of the case X. It is arranged.

  The case X is a container that accommodates many articles of the same type. In principle, a single case X contains a plurality of articles of the same type. However, a plurality of types of articles may be accommodated in each case X. Further, depending on the stock status, there may be a case where only one article of the same type is accommodated in the case X.

  As shown in FIG. 1, the ground system 4 includes an upstream conveyor 4a and a downstream conveyor 4b that convey containers. Further, as shown in FIG. 2, the ground system 4 includes a ground control unit 4 c that controls the upstream conveyor 4 a and the downstream conveyor 4 b, a first communication module 4 d for communicating with the host system, a robot carriage 5, A second communication module 4e for communicating and a third communication module 4f for communicating with the container cart 6 are provided.

  The upstream conveyor 4a is a roller conveyor that conveys an empty container Y to the container transfer region R shown in FIG. The downstream conveyor 4b is a roller conveyor that conveys the container Y in which articles are stored from the container transfer region R to an unillustrated unloading location. The upstream conveyor 4a and the downstream conveyor 4b can be belt conveyors instead of roller conveyors. The upstream conveyor 4a and the downstream conveyor 4b convey the container Y under the control of the ground control unit 4c. The container Y is a container for storing articles delivered to a predetermined shipping destination, and can be folded, for example.

  The ground control unit 4c is configured to transmit the upstream conveyor 4a and the downstream conveyor based on a command input from the host system (for example, a system that controls the entire logistics facility including the picking facility 1) via the first communication module 4d. This is a programmable controller that controls 4b. In the picking facility 1 of the present embodiment, the ground control unit 4 c also controls the robot cart 5 and the container cart 6. For example, the ground control unit 4c controls the robot cart 5 by communicating with the robot cart 5 through the second communication module 4e. The ground control unit 4c controls the container cart 6 by communicating with the container cart 6 through the third communication module 4f.

  The first communication module 4d, the second communication module 4e, and the third communication module 4f are transmission modules that perform wireless communication using light or radio waves. The first communication module 4d is a transmission module for the ground control unit 4c to communicate with the host system. The second communication module 4 e is a transmission module for the ground control unit 4 c to communicate with a general control unit 5 e described later of the robot cart 5. The third communication module 4f is a transmission module for the ground control unit 4c to communicate with a container cart control unit 6c, which will be described later, of the container cart 6.

  As shown in FIG. 1, the robot cart 5 includes a cart unit 5a, a picking robot 5b, and an article determination camera 5c. As shown in FIG. 2, the robot cart 5 includes an article discrimination control processing unit 5d, a general control unit 5e, a switch 5f, and a communication module 5g.

  The carriage unit 5a supports the picking robot 5b and can travel along the rail 2. As shown in FIG. 2, the cart unit 5a includes a travel mechanism 5a1 and a travel control unit 5a2. The traveling mechanism 5a1 is a mechanism that allows the carriage unit 5a to travel, and includes wheels and a drive motor (not shown). The traveling control unit 5a2 is a programmable controller that controls the traveling mechanism 5a1, and controls the traveling mechanism 5a1 based on a command from the overall control unit 5e. The traveling control unit 5a2 is connected to the communication module 5g through the switch 5f.

  The picking robot 5b is an industrial robot for transferring articles accommodated in the case X to the container Y. As shown in FIG. 2, the robot body 5b1, the robot controller 5b2, the picking mechanism 5b3, It has. The robot body 5b1 is a multi-axis robot having a plurality of joints and drive motors, and is driven by the robot controller 5b2. The robot control unit 5b2 is connected to the general control unit 5e, and controls the robot main body unit 5b1 based on a command from the general control unit 5e. The picking mechanism 5b3 is a mechanism for lifting an article, and includes, for example, a suction pad installed at the distal end portion of the robot body 5b1 and an exhaust device that supplies negative pressure to the suction pad.

  The article discrimination camera 5c is provided at the tip of the picking robot 5b. The article discrimination camera 5c images the inside of the case X under the control of the article discrimination control processing unit 5d, and acquires image data including information such as the type and posture of the article accommodated in the case X. Further, the article discrimination camera 5c outputs image data acquired by taking an image to the article discrimination control processing unit 5d. The article discrimination control processing unit 5d discriminates the type of article accommodated in the case X and the attitude of the article based on the image data input from the article discrimination camera 5c, and the discrimination result is directed to the general control unit 5e. Output. The article discrimination control processing unit 5d is connected to the communication module 5g via the switch 5f. The article determination camera 5c and the general control unit 5e function as a recognition unit that is installed in the robot carriage 5 and recognizes an article stored in the case X.

  The general control unit 5e is connected to the communication module 5g via the switch 5f, and is based on a command input from the ground control unit 4c and a determination result input from the article determination control processing unit 5d. 5a and a programmable controller that generates operation commands for the picking robot 5b. The general control unit 5e outputs command signals to the travel control unit 5a2 of the carriage unit 5a, the robot control unit 5b2 of the picking robot 5b, and the picking mechanism 5b3. The general control unit 5e also includes a signal indicating the state of the cart unit 5a input from the travel control unit 5a2 of the cart unit 5a, and a signal indicating the status of the robot body unit 5b1 input from the robot control unit 5b2 of the picking robot 5b. And the signal which shows the state of the picking mechanism 5b3 is transmitted to the ground control part 4c via the communication module 5g.

  The switch 5f is connected to the travel control unit 5a2, the article discrimination control processing unit 5d, and the general control unit 5e, and these are selected and connected to the communication module 5g. That is, the switch 5f disconnects the article determination control processing unit 5d and the general control unit 5e from the communication module 5g when the travel control unit 5a2 is connected to the communication module 5g. Further, when the article discrimination control processing unit 5d is connected to the communication module 5g, the switch 5f disconnects the traveling control unit 5a2, the general control unit 5e, and the communication module 5g. Further, when the general control unit 5e is connected to the communication module 5g, the switch 5f disconnects the travel control unit 5a2, the article determination control processing unit 5d, and the communication module 5g. The communication module 5g is a transmission module for communicating with the ground control unit 4c, and is wirelessly connected to the second communication module 4e of the ground system 4.

  As shown in FIG. 1, the container cart 6 includes a cart unit 6 a and a transfer conveyor 6 b (transfer device). Moreover, the container trolley | bogie 6 is provided with the container trolley | bogie control part 6c and the communication module 6d, as shown in FIG.

  The carriage unit 6a is mounted with a transfer conveyor 6b and is capable of traveling along the rail 2, and has a traveling mechanism 6a1 as shown in FIG. The traveling mechanism 6a1 is a mechanism that allows the carriage unit 6a to travel, and includes wheels (not shown) and a drive motor. Such a carriage unit 6 a can travel along the rail 2 in a state separated from the robot carriage 5.

  The transfer conveyor 6b is a roller conveyor mounted on the carriage unit 6a so as to have substantially the same height as the upstream conveyor 4a and the downstream conveyor 4b of the ground system 4. The transfer conveyor 6b can be a belt conveyor instead of a roller conveyor. Such a transfer conveyor 6b receives an empty container Y conveyed to the container transfer area R shown in FIG. 1 by the upstream conveyor 4a of the ground system 4, and transfers the container Y containing articles to the container. Transfer from the region R to the downstream conveyor 4b.

  Thus, in this embodiment, the container carriage 6 is configured to be able to place the container Y on the transfer conveyor 6b by including the transfer conveyor 6b that transfers the container Y. Further, the container cart 6 is allowed to travel on the rail 2 separately from the robot cart 5 in a state where the container Y is placed.

  The container trolley controller 6c is a programmable controller that controls the traveling mechanism 6a1 and the transfer conveyor 6b of the trolley 6a. The container trolley controller 6c and the transfer mechanism 6a1 are transferred based on a command from the ground controller 4c that is input through the communication module 6d. The conveyor 6b is controlled. The communication module 6d is a transmission module for communicating with the ground control unit 4c, and is wirelessly connected to the third communication module 4f of the ground system 4.

  Then, with reference to FIGS. 3-9, operation | movement of the picking equipment 1 of this embodiment is demonstrated. FIG. 3 is a flowchart for explaining the operation of the ground control unit 4c. FIG. 4 is a flowchart for explaining the operation of the general control unit 5e of the robot carriage 5. FIG. 5 is a flowchart for explaining the operation of the travel control unit 5a2 of the robot carriage 5. FIG. 6 is a flowchart for explaining the operation of the article discrimination control processing unit 5d of the robot carriage 5. FIG. 7 is a flowchart for explaining the operation of the container cart controller 6c. 8 and 9 are schematic diagrams for explaining the operation of the robot cart 5 and the container cart 6. FIG.

  As shown in FIG. 3, the ground control unit 4c transmits picking information to the general control unit 5e of the robot carriage 5 based on a command input from the host system through the first communication module 4d (step S1a). In addition, the ground control unit 4c transmits the picking information to the container cart control unit 6c of the container cart 6 (step S1b). Here, the picking information is information including a signal indicating the start of picking work, the address of the case X in which the article to be picked is accommodated, the number of articles to be picked, and the like.

  Subsequently, the ground control unit 4c waits until a signal indicating that the movement from the container carriage 6 to the container transfer region R is completed and the container Y can be transferred is received (step S1c). When the ground control unit 4c receives a signal indicating that the container Y can be transferred from the container cart 6 in step S5c described later, the ground control unit 4c transmits an instruction to start the transfer of the container Y to the container cart 6 (step S5c). S1d). Moreover, the ground control part 4c performs a conveyor drive process (step S1e). In the conveyor driving process, the ground control unit 4c drives the upstream conveyor 4a and causes the upstream conveyor 4a to transport an empty container Y to the container transfer region R.

  Subsequently, the ground control unit 4c stands by until a signal indicating that the transfer of the container Y is completed from the container cart 6 (step S1f). When the ground control unit 4c receives a signal indicating that the transfer of the container Y has been completed from the container cart 6 in step S5f described later, the ground control unit 4c transmits an instruction to move to the side of the robot cart 5 to the container cart 6. (Step S1g). Subsequently, the ground control unit 4c waits until it receives a signal indicating that it has moved from the container cart 6 to the side of the robot cart 5 (step S1h), and further, the article accommodated in the target case X from the robot cart 5 The process waits until a signal indicating that the picking operation is completed is received (step S1i).

  The ground control unit 4c receives a signal indicating that it has moved from the container carriage 6 to the side of the robot carriage 5 in step S5i, which will be described later, and picks an article accommodated in the target case X from the robot carriage 5 in step S2h, which will be described later. When a signal indicating that the work has been completed is received, an instruction for synchronous operation is transmitted to the container cart 6 (step S1j). Here, the synchronous operation means that the operation always accompanying the robot cart 5 is performed in synchronization with the robot cart 5. Thereafter, the ground control unit 4c stands by (step S1k) until a signal indicating that synchronous operation is being performed from the container cart 6 in step S5m described later. When the ground control unit 4c receives a signal indicating that the vehicle is in synchronous operation from the container cart 6, the ground control unit 4c transmits a place instruction including information for picking other articles to the robot cart 5 (step S1m). Thereafter, the ground control unit 4c stands by until a signal indicating that the place work has been completed is received from the robot carriage 5 (step S1n).

  When the signal indicating that the place work has been completed is received from the robot carriage 5 in step S2m described later, the ground control unit 4c transmits an instruction to the container carriage 6 to move to the container transfer area R (step S1p). ). And it waits until it receives the signal to the effect that it was ready to transfer the container Y from the container cart 6 (step S1q). And the ground control part 4c will transmit the instruction | indication which starts the transfer of the container Y with respect to the container trolley 6 if the signal to the effect that the container Y can be transferred from the container trolley 6 by step S5q mentioned later is received. (Step S1r). Moreover, the ground control part 4c performs a conveyor drive process (step S1s). In this conveyor driving process, the ground control unit 4c drives the downstream conveyor 4b and conveys the container Y in which articles are stored in the downstream conveyor 4b from the container transfer area R to a predetermined external location.

  Subsequently, the ground control unit 4c stands by until a signal indicating that the transfer is completed is received from the container cart 6 (step S1t). When the ground control unit 4c receives a signal indicating that the transfer is completed from the container carriage 6 in step S5t described later, the ground control unit 4c returns to step S1c described above.

  As shown in FIG. 4, the overall control unit 5e waits until receiving a command including picking information transmitted from the ground control unit 4c in the above-described step S1a (step S2a). When the general control unit 5e receives a command including picking information, the general control unit 5e transmits a movement command to the travel control unit 5a2 based on the command (step S2b). This movement command includes the address of the case X that accommodates an article to be picked by the robot carriage 5.

  Subsequently, the overall control unit 5e waits until receiving a signal indicating that the picking is possible from the travel control unit 5a2 (step S2c). When the general control unit 5e receives a signal indicating that the picking is possible from the travel control unit 5a2 in step S3c described later, the article determination camera 5c is positioned so that the article can be recognized. Recognition position movement processing is performed (step S2d). Here, the overall control unit 5e causes the robot control unit 5b2 to drive the robot body 5b1, thereby moving the article determination camera 5c to a position where the article can be recognized. Then, when the recognition position process is completed, the general control unit 5e instructs the article discrimination control processing unit 5d to start the recognition of the article (Step S2e). Thereafter, the overall control unit 5e stands by until a signal indicating that the recognition of the article has been completed is received from the article discrimination control processing unit 5d (step S2f).

  When the overall control unit 5e receives a signal indicating that the recognition of the article is completed from the article discrimination control processing unit 5d in step S4c described later, the overall control unit 5e performs a picking process (step S2g). Here, the overall control unit 5e causes the robot control unit 5b2 to control the robot body 5b1 based on the information acquired by the article discrimination control processing unit 5d, and further controls the picking mechanism 5b3, thereby The article accommodated in is moved to the container Y. When the picking process is completed, the general control unit 5e transmits a signal indicating that the picking process has been completed to the ground control unit 4c of the ground system 4 (step S2h).

  Subsequently, the overall control unit 5e waits until a command including a place instruction transmitted from the ground control unit 4c in step S1m is received (step S2i). When the general control unit 5e receives a command including a place instruction from the ground control unit 4c, the general control unit 5e starts a place (step S2j) and issues a travel permission to the travel control unit 5a2 (step S2k). Then, when the place is completed, the general control unit 5e transmits a signal indicating that to the ground control unit 4c (step S2m). When the transmission indicating that the place is completed is completed, the overall control unit 5e returns to step S2c described above.

  As shown in FIG. 5, the traveling control unit 5a2 waits until it receives the movement command transmitted from the overall control unit 5e in step S2b described above (step S3a). When the travel control unit 5a2 receives the movement command transmitted from the general control unit 5e, the travel control unit 5a2 performs the movement process of the robot carriage 5 (step S3b). Here, the traveling control unit 5a2 controls the traveling mechanism 5a1 based on the movement command input from the general control unit 5e, thereby moving the robot carriage 5 to the vicinity of the case X in which the article to be picked is accommodated. When the movement of the robot carriage 5 is completed, the travel control unit 5a2 transmits a signal indicating that the movement is completed and picking is possible to the general control unit 5e (step S3c).

  Subsequently, the traveling control unit 5a2 waits until it receives the movement command transmitted from the overall control unit 5e in step S2k described above (step S3d). When the travel control unit 5a2 receives the movement command transmitted from the general control unit 5e, the travel control unit 5a2 performs the movement process of the robot carriage 5 (step S3e). The traveling control unit 5a2 controls the traveling mechanism 5a1 based on the movement command input from the general control unit 5e, thereby moving the robot carriage 5 to the vicinity of the case X in which an article to be picked next is accommodated. When the movement of the robot carriage 5 is completed, the traveling control unit 5a2 returns to step S3c described above.

  As illustrated in FIG. 6, the article determination control processing unit 5d waits until receiving a recognition start instruction transmitted from the overall control unit 5e in the above-described step S2e (step S4a). When receiving the recognition start instruction transmitted from the overall control unit 5e, the article discrimination control processing unit 5d performs a recognition process (step S4b). Here, the article discrimination control processing unit 5d causes the article discrimination camera 5c to image the article contained in the case X, and discriminates the type and posture of the article from the imaging data. And the article | item discrimination | determination control processing part 5d will transmit the signal which shows that to the general control part 5e, if the recognition process is completed (step S4c). Thereafter, the article discrimination control processing unit 5d returns to Step S4a.

  As shown in FIG. 7, the container cart controller 6c waits until it receives a command including picking information transmitted from the ground controller 4c in step S1b described above (step S5a). When receiving a command including picking information, the container cart control unit 6c performs a cart movement process based on the command (step S5b). In this cart movement process, the container cart control unit 6c controls the traveling mechanism 6a1 based on the command input from the ground control unit 4c, thereby bringing the container cart 6 into the robot cart 5 as shown in FIG. And move to the container transfer area R.

  When the container cart control unit 6c moves to the container transfer region R, the container cart control unit 6c transmits a signal indicating that the container Y can be transferred to the ground control unit 4c (step S5c). Then, the container carriage control unit 6c waits until it receives the container transfer instruction transmitted from the ground control unit 4c in step S1d described above (step S5d). When the container transfer instruction is received, the container cart control unit 6c performs a conveyor driving process (step S5e). Here, the container trolley controller 6c drives the transfer conveyor 6b, and transfers an empty container Y that has been transported to the container transfer region R by the upstream conveyor 4a under the control of the ground control unit 4c. Received on the conveyor 6b side.

  Subsequently, when the transfer of the container Y is completed, the container carriage control unit 6c transmits a signal indicating that to the ground control unit 4c (step S5i). Then, the container carriage control unit 6c waits until it receives an instruction to move to the side of the robot carriage 5 transmitted from the ground control unit 4c in step S1g (step S5j). When receiving an instruction to move the robot cart 5 to the side, the container cart control unit 6c causes the container cart 6 to run in synchronization with the robot cart 5 as shown in FIG. 8B (step S5k). Furthermore, the container cart control unit 6c transmits a signal indicating that the vehicle is traveling in synchronization with the robot cart 5 to the ground control unit 4c (step S5m).

  Subsequently, the container cart control unit 6c continues the synchronous operation with the robot cart 5 until it receives the container cart movement instruction transmitted from the ground control unit 4c in step S1p described above (step S5n). And the container trolley control part 6c will perform a trolley | bogie movement process, if the container trolley | bogie movement instruction | command transmitted from the ground control part 4c is received (step S5p). In this cart movement process, the container cart control unit 6c controls the traveling mechanism 6a1 based on the command input from the ground control unit 4c, thereby bringing the container cart 6 into the robot cart 5 as shown in FIG. And move to the container transfer area R.

  When the container cart control unit 6c moves to the container transfer region R, the container cart control unit 6c transmits a signal indicating that the container Y can be transferred to the ground control unit 4c (step S5q). Then, the container carriage control unit 6c stands by until it receives the container transfer instruction transmitted from the ground control unit 4c in the above-described step S1r (step S5r). When the container transfer instruction is received, the container carriage control unit 6c performs a conveyor driving process (step S5s). Here, the container trolley controller 6c drives the transfer conveyor 6b, and delivers the container Y containing the articles from the container transfer area R to the downstream conveyor 4b as shown in FIG. 9B. Then, when the transfer of the container Y is completed, the container cart control unit 6c transmits a signal indicating that to the ground control unit 4c (step S5t), and returns to step S5c.

  The picking equipment 1 of the present embodiment includes a container cart 6 that can travel separately from the robot cart 5 on which the picking robot 5b is mounted. For this reason, the operation | work which delivers the container Y with respect to the container trolley | bogie 6 and the operation | work by the robot trolley | bogie 5 can be performed in parallel. Therefore, according to the picking facility 1 of the present embodiment, it is possible to shorten the loading operation period of articles to one container Y.

  In addition, the picking facility 1 of the present embodiment includes an article discrimination camera 5c and an article discrimination control processing unit 5d as a recognition unit that is installed on the robot carriage 5 and recognizes an article accommodated in the case X. The container carriage control unit 6c that moves the container Y by moving the container carriage 6 separately from the robot carriage 5 during the recognition is provided. For this reason, according to the picking equipment 1 of the present embodiment, movement of the container Y is not restricted during recognition of an article that requires time for processing because it involves image processing. Therefore, it is possible to further shorten the loading operation period of articles for one container Y.

  Moreover, in the picking equipment 1 of this embodiment, the container trolley | bogie 6 is provided with the transfer conveyor 6b which functions as a transfer apparatus which transfers the container Y. FIG. For this reason, it is not necessary to install a transfer device separately from the container cart 6, and the overall configuration of the picking facility 1 can be simplified.

  In addition, while the picking robot 5 b transfers articles from the plurality of cases X to the container Y, the container cart 6 is moved in synchronization with the robot cart 5. By adopting such a configuration, the articles picked up by the picking robot 5b can be quickly stored in the container Y, and the waiting time of the picking robot 5b can be reduced.

  Further, the picking equipment 1 of the present embodiment includes a flow rack 3 on which the case X is placed and a rail 2 laid along the flow rack 3, and the robot carriage 5 and the container carriage 6 are the same. It is possible to travel along the rail 2. For this reason, the container carriage 6 can be moved along the rails 2 to the side of the robot carriage 5 easily and in a short time.

  As mentioned above, although preferred embodiment of this invention was described referring an accompanying drawing, it cannot be overemphasized that this invention is not limited to the said embodiment. Various shapes, combinations, and the like of the constituent members shown in the above-described embodiments are examples, and various modifications can be made based on design requirements and the like without departing from the spirit of the present invention.

  For example, in the above embodiment, a configuration in which one container carriage 6 is provided for one robot carriage 5 is employed. However, the present invention is not limited to this, and a configuration in which the container cart 6 is arranged on both sides of one robot cart 5 may be adopted. In such a case, for example, it is preferable that the container transfer region R is provided on both sides of the container cart 6.

  Moreover, in the said embodiment, the structure which the robot trolley | bogie 5 and the container trolley | bogie 6 drive along the rail 2 was demonstrated. However, the present invention is not limited to this, and an automatic traveling cart that travels on a floor surface on which no rail is laid may be used as a robot cart and a container cart.

  Moreover, in the said embodiment, the structure provided with the transfer conveyor 6b in the container trolley | bogie 6 was demonstrated. However, the present invention is not limited to this, and it is also possible to adopt a configuration in which a transfer device for transferring the container Y is provided separately from the container cart 6.

  Moreover, in the said embodiment, the structure which uses case X as an article | item container was demonstrated. However, the present invention is not limited to this, and a pallet or the like may be used as the article container.

  Moreover, in the picking equipment 1 of the said embodiment, the structure which the robot cart 5 and the container cart 6 drive the same rail 2 was employ | adopted. However, the present invention is not limited to this. FIG. 10 is a plan view schematically showing a schematic configuration of a modification of the picking facility 1 of the embodiment. As shown in this figure, the rail 2 may be the first rail that only the robot carriage 5 travels, and the second rail 7 that only the container carriage 6 travels may be laid. In such a case, the flow rack 3 is arranged only on one side of the rail 2, and the second rail 7 is laid on the opposite side of the rail 2 from the flow rack 3 in parallel to the rail 2. Further, an upstream conveyor 4 a and a downstream conveyor 4 b are arranged along the second rail 7. By adopting such a configuration, the robot cart 5 and the container cart 6 do not interfere with each other, so that the robot cart 5 and the container cart 6 can be moved more freely.

  Next, with reference to FIGS. 11 to 13, a picking facility 1 </ b> A that is a second embodiment of the present invention and includes a camera carriage 7 (recognition unit carriage) instead of the article determination camera 5 c will be described. In the second embodiment, the description of the same parts as those in the above embodiment is omitted.

  FIG. 11 is a plan view schematically showing a schematic configuration of the picking equipment 1A of the present embodiment. As shown in this figure, the picking equipment 1 </ b> A of the present embodiment includes a camera carriage 7 and a rail 8 that guides the camera carriage 7. As shown in FIG. 11, the picking facility 1 </ b> A according to the present embodiment includes two pairs of camera carts 7 and rails 8.

  The camera carriage 7 can travel along the flow rack 3 by rails 8 laid above the robot carriage 5. FIG. 12 is a functional block diagram showing a schematic configuration of the picking facility 1A in the second embodiment of the present invention. As shown in this figure, the camera cart 7 includes a cart unit 7a, an article discrimination camera 7b, an article discrimination control processing unit 7c, a camera cart control unit 7d, and a communication module 7e. In FIG. 12, only one camera carriage 7 is shown, but in the picking facility 1A of the present embodiment, another camera carriage 7 having the same configuration is provided.

  The carriage unit 7a can travel along the rail 8, and has a traveling mechanism 7a1 as shown in FIG. The traveling mechanism 7a1 is a mechanism that allows the carriage unit 7a to travel, and includes wheels (not shown) and a drive motor. Such a carriage unit 7 a is provided separately from the robot carriage 5 and can travel along a rail 8 different from the rail 2 on which the robot carriage 5 travels.

  The article determination camera 7b is provided downward with respect to the carriage unit 7a. The article discrimination camera 7b images the inside of the case X under the control of the article discrimination control processing unit 7c, and acquires image data including information such as the type and posture of the article accommodated in the case X. Further, the article discrimination camera 7b outputs image data acquired by taking an image to the article discrimination control processing unit 7c. The article discrimination control processing unit 7c discriminates the type of article contained in the case X and the attitude of the article based on the image data input from the article discrimination camera 7b, and the discrimination result is transmitted via the communication module 7e. Output toward the ground control unit 4c. The article discrimination camera 7b and the article discrimination control processing unit 7c function as a recognition unit that recognizes an article accommodated in the case X.

  The camera cart control unit 7d is connected to the communication module 7e, and based on a command input from the ground control unit 4c and a discrimination result input from the article discrimination control processing unit 5d, an operation command for the cart unit 7a. Is a programmable controller that generates The communication module 7e is a transmission module for communicating with the ground control unit 4c, and is wirelessly connected to the fourth communication module 4g of the ground system 4.

  FIG. 13 is a flowchart for explaining the operation of the picking facility 1A of the present embodiment. As shown in this figure, in the picking equipment 1A of the present embodiment, under the control of the ground control unit 4c, the recognition position movement process in step S2d and the recognition start instruction in step S2e are the carriage movement command and step in step S2b. This is performed in parallel with the standby process until a signal indicating that picking is possible is received from the traveling control unit 5a2 in S2c.

  According to the picking facility 1 </ b> A of this embodiment, the article determination camera 7 b that recognizes the article stored in the case X is mounted on the camera carriage 7 that can travel separately from the robot carriage 5. For this reason, the robot cart 5 can be moved without waiting for imaging by the article discrimination camera 7b.

  Furthermore, by moving the container carriage 6 during imaging with the article discrimination camera 7b, identification of the state of the article, operation of the robot body 5b1, and movement of the container carriage 6 can be performed in parallel. It is possible to shorten the time for the picking process.

  Further, in the picking facility 1 </ b> A of the present embodiment, the camera carriage 7 is supported so as to be able to travel above the robot carriage 5. For this reason, the camera carriage 7 can be moved without interfering with the robot carriage 5.

  In the picking facility 1A of the present embodiment, a laser measuring instrument or the like is installed in place of the article discrimination camera 5c or together with the article discrimination camera 5c, and the distance to the article, the article is determined based on the measurement result of the laser instrument etc. The shape, the posture of the article, etc. may be acquired.

  In addition, in the picking facility 1A of the present embodiment, it is possible to adopt a configuration that allows the camera carriage 7 to run on a rail laid on the ground without hanging and supporting the camera carriage 7. In the case of adopting such a configuration, it is conceivable to arrange the article discrimination camera 7b so that the rail 8 is laid in parallel with the rail 2 and the case X can be imaged.

  DESCRIPTION OF SYMBOLS 1 ... Picking equipment, 2 ... Rail, 3 ... Flow rack (rack), 4 ... Ground system, 4a ... Upstream conveyor, 4b ... Downstream conveyor, 4c ... Ground control part, 4d ... 1st communication module, 4e... 2nd communication module, 4f... 3rd communication module, 5... Robot cart, 5a... Cart unit, 5a1 .. travel mechanism, 5a2. Robot, 5b1 ... Robot body, 5b2 ... Robot controller, 5b3 ... Picking mechanism, 5c ... Article discriminating camera, 5d ... Article discriminating control processing unit, 5e ... General control unit, 5f ... Switch, 5g: Communication module, 6: Container cart, 6a: Cart unit, 6a1: Traveling mechanism, 6b: Transfer conveyor (transfer device), 6c: Container cart control unit, 6d: Communication Joule, 7 ... Robot cart, 7a ... Cart unit, 7a1 ... Traveling mechanism, 7b ... Article discrimination camera, 7c ... Article discrimination control processing unit, 7d ... Camera cart control unit, R ... Container transfer Area, X ... Case (goods container), Y ... Container

Claims (10)

Picking equipment for transferring an article stored in an article container by a picking robot to a container,
A robot carriage that is capable of traveling with the picking robot mounted thereon;
A picking facility, comprising: a container cart that is capable of placing the container and is capable of traveling separately from the robot cart. A recognition unit that is installed in the robot carriage and recognizes an article stored in the article container;
The picking facility according to claim 1, further comprising: a container cart control unit that moves the container by causing the container cart to travel separately from the robot cart while the article is being recognized by the recognition unit. .   The picking facility according to claim 1, wherein the container cart includes a transfer device that transfers the container. A rack on which the article container is placed; and a rail laid along the rack;
The picking equipment according to any one of claims 1 to 3, wherein the robot carriage and the container carriage are allowed to travel along the same rail.   A rack on which the article container is placed; a first rail that is laid along the rack and on which the robot carriage runs; and is parallel to the first rail and opposite the rack with respect to the first rail The picking equipment according to any one of claims 1 to 3, further comprising a second rail that is laid on a side and on which the container carriage travels.   The container cart is moved in synchronization with the robot cart when the robot cart is moved to another location, and the article can be transferred from the picking robot to the container cart. Picking equipment as described in any one of 1-5.   The picking facility according to any one of claims 1 to 6, comprising a plurality of the container carts.   2. The picking facility according to claim 1, further comprising a recognition unit carriage that has a recognition unit that recognizes an article accommodated in the article container and is capable of traveling.   9. The picking equipment according to claim 8, further comprising a container cart control unit that moves the container by causing the container cart to travel separately from the robot cart while the article is being recognized by the recognition unit. .   The picking equipment according to claim 8 or 9, wherein the recognition unit carriage is suspended and supported so as to be able to travel above the robot carriage.

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