JP2019137496A - Storage system - Google Patents

Abstract

To attain a picking operation according to each commodity in a storage system.SOLUTION: A storage system includes: placing shelves where shelves on which a plurality of commodity boxes including mutually different types of commodities are arranged in a first direction are formed in a step-like state toward a second direction; first conveyance devices respectively installed along the plurality of commodity boxes on each step and conveying a container in the first direction; second conveyance devices respectively installed along the end part positions of the respective first conveyance devices, receiving the container between the respective first conveyance devices, and conveying the container in the second direction; and picking devices taking out the commodities from corresponding commodity boxes and storing them in the container conveyed to a prescribed position in each step. The picking devices take out the commodities at positions designated by a worker in images in the commodity boxes captured before taking out the commodities from the commodity boxes in the order designated by the worker from the commodity boxes.SELECTED DRAWING: Figure 3

Description

  The present invention relates to a storage system.

  2. Description of the Related Art Conventionally, storage systems that store products in containers prepared for each delivery destination store are known. For example, in Patent Document 1 below, a plurality of product boxes filled with each type of product are arranged in a row, and each type of product is stored in a container while being transported by a conveyor installed along the product box. A system for storing in a container is disclosed.

  In the system, a picking device installed for each product box takes out the product from the product box and stores it in the transported container. Thereby, in the said system, the goods of the kind and quantity predetermined for every store can be stored in a container.

JP-A-2015-193467

  However, in the case of the above-mentioned system, there is a problem that when the number of types of products increases, the number of picking devices increases and the rows of product boxes also increase, so that the space for installing the system increases. In addition, when replacement with a new product is frequently performed or product shapes are diversified, it is assumed that it is difficult to realize a picking operation according to the product in each picking device.

  An object of one aspect is to realize a picking operation according to each product in a storage system that can be installed in a small space.

According to one aspect, the storage system comprises:
A shelf in which a plurality of product boxes containing different types of products are arranged in a first direction, a mounting shelf formed in a stepped shape in the second direction,
A first transport device installed along each of the plurality of product boxes at each stage and transporting a container in the first direction;
A second transport device installed along an end position of each of the first transport devices, transferring the container to and from each of the first transport devices, and transporting the container in the second direction;
In each stage, the container transported to a predetermined position has a picking device that takes out and stores the product from the corresponding product box,
The picking device takes out products at a position specified by an operator from the product box in an order specified by the operator in an image in the product box taken before taking out the product from the product box. And

  In a storage system that can be installed in a space-saving manner, a picking operation corresponding to each product can be realized.

It is a figure which shows the structural example of the whole warehouse area containing a storage system. It is a side view which shows the structure of a storage system. It is a top view which shows the structure of a storage system. It is a front view which shows the structure of a storage system. It is a figure which shows an example of the hardware constitutions of a control apparatus. It is a figure which shows an example of a function structure of the storage system which concerns on 1st Embodiment. It is a figure which shows an example of supplement information. It is a figure which shows an example of a function structure of a conveyor control part. It is a figure which shows the operation example of a conveying apparatus. It is a flowchart which shows the flow of the conveyance control processing by a conveying apparatus. It is a figure which shows an example of a function structure of a robot movable control part. It is a figure which shows the operation example of a robot movable mechanism part. It is a flowchart which shows the flow of the robot movement process by a robot movable mechanism part. It is a figure which shows an example of a function structure of a camera movement control part. It is a figure which shows the operation example of a camera movable mechanism part. It is a flowchart which shows the flow of the camera movement process by a camera movable mechanism part. It is a figure which shows an example of a function structure of a picking control part. It is a figure which shows the operation example at the time of the goods extraction of a robot part. It is a figure which shows the operation example at the time of goods storage of a robot part. It is a flowchart which shows the flow of a robot control process (takeout). It is a flowchart which shows the flow of a robot control process (storage). It is a figure which shows an example of a function structure of an empty box delivery control part. It is a figure which shows the operation example of the robot part at the time of empty box payout. It is a figure which shows the operation example of the conveying apparatus at the time of empty box discharge. It is a flowchart which shows the flow of the empty box payout process by a robot part. It is a figure which shows an example of a function structure of the storage system which concerns on 2nd Embodiment. It is a 1st figure which shows an example of a function structure of a remote control part. It is a 1st flowchart which shows the flow of the remote control process by a remote control part. It is a 1st figure which shows the operation example of a remote control part. It is a 2nd figure which shows an example of a function structure of a remote control part. It is a 2nd flowchart which shows the flow of the remote control process by a remote control part. It is a 2nd figure which shows the operation example of a remote control part. It is a figure which shows an example of a function structure of the storage system which concerns on 3rd Embodiment. It is a 3rd figure which shows an example of a function structure of a remote control part. It is a 3rd flowchart which shows the flow of the remote control process by a remote control part. It is a 3rd figure which shows the operation example of a remote control part. It is a 4th figure which shows an example of a function structure of a remote control part. It is a 4th flowchart which shows the flow of the remote control process by a remote control part. It is a 4th figure which shows the operation example of a remote control part. It is a figure which shows an example of a function structure of a whole control part. It is a figure which shows the operation example of a whole control part. It is a figure which shows the other structural example of a storage system. It is a flowchart which shows the flow of the picking instruction | indication data output process by the whole control part.

  Each embodiment will be described below with reference to the accompanying drawings. In addition, in this specification and drawing, about the component which has the substantially same function structure, the duplicate description is abbreviate | omitted by attaching | subjecting the same code | symbol.

[First Embodiment]
<Composition of the entire warehouse area>
First, the configuration of the entire warehouse area including the storage system will be described. FIG. 1 is a diagram illustrating a configuration example of the entire warehouse area including the storage system. As shown in FIG. 1, a general computer 110 is installed in the warehouse area, and manages each of a product storage area 120, a storage area 140, and a delivery area 150.

  The product storage area 120 is an area for storing various products brought in from the outside. The products stored in the product storage area 120 are packed in a product box for each product type, and are brought into the storage area 140 for each product box.

  A storage system 130 is installed in the storage area 140. The storage system 130 takes out a predetermined quantity of products from a product box packed with a predetermined type of product among each product box, and stores a folding container (hereinafter, referred to as a “folding container” prepared for each delivery destination store). Simply referred to as a “container”). The container in which the product is stored is carried into the delivery area 150. In addition, the product box (empty box) from which the product has been taken out and emptied is carried out to the outside.

  The storage system 130 includes a mounting shelf 132 on which a product box is mounted. In addition, the storage system 130 includes a transport device 133 that is installed around the mounting shelf 132 and transports the container, and a picking device 134 that takes out the product from the product box and stores it in the transported container. Furthermore, the storage system 130 includes a control device 131 that controls the transport device 133 and the picking device 134.

  The delivery area 150 is an area for mounting a container carried in from the storage area 140 (a container in which products are stored) on a vehicle or the like and delivering it to a delivery destination store.

<Configuration of storage system>
Next, the configuration of the storage system 130 will be described. FIG. 2 is a side view showing the configuration of the storage system. As shown in FIG. 2, the mounting shelf 132 in the storage system 130 has a plurality of shelves (four in the example of FIG. 2) in the height direction. The shelves of each stage included in the mounting shelf 132 have different lengths in the y-axis direction (second direction), and the length in the y-axis direction is shorter as they go to the upper stage. For this reason, in the case of FIG. 2, the position of the left end portion of each shelf is shifted in the y-axis direction, and the entire mounting shelf 132 is formed in a step shape in the y-axis direction (that is, The mounting shelf 132 has a stepped structure).

  A product box (for example, product box 240) is placed on each shelf of the placement shelf 132. In the case of FIG. 2, the product boxes placed on the shelves of each stage are replenished by the operator 260 from the position of the right end of the shelves of each stage.

  Further, in the storage system 130, the transport device 133 is a first transport device that is further above the conveyors 201, 202, 203, and 204 installed at the position of the left end of each shelf and the shelf on the top. And an installed conveyor 205. The first transport device transports a container (for example, container 250).

  Moreover, the conveying apparatus 133 has the conveyor 210 as a 2nd conveying apparatus. The conveyor 210 conveys the container 250 in the y-axis direction, and exchanges containers with the conveyors 201 to 205.

  In the example of FIG. 2, the case where the conveyor 210 having an oblique surface along the y-axis direction is installed as the second conveying device is shown, but the second conveying device is not limited to the conveyor. For example, the second transport device may have a structure in which a step-like flat surface is translated obliquely along the y-axis direction, like an escalator. Alternatively, the second transport device has a structure in which a conveyor that transports the container horizontally in the y-axis direction and a lift that moves the container up and down in the z-axis direction at the position of the first transport device are combined. Also good.

  Further, in the storage system 130, the picking device 134 includes a camera unit 221 to 224 installed in the vicinity (upper side) of the product box placed on the left end of each shelf in the example of FIG. ˜234. As shown in FIG. 2, the position of the left end of each shelf of the mounting shelf 132 is shifted in the y-axis direction by one product box or more. For this reason, in the example of FIG. 2, the camera units 221 to 224 and the robot units 231 to 234 can access the product box placed on the left end portion of each shelf from above.

  The camera units 221 to 224 photograph the inside of the product box at the corresponding position and the inside of the container at the position corresponding to the product box. The robot units 231 to 234 take out the products in the product box at the corresponding positions. Further, the robot units 231 to 234 store the taken-out products in a container located at a position corresponding to the product box.

  When all the products in the product box are taken out and become empty boxes, the robot units 231 to 234 pay out the empty boxes toward the first transfer device (any one of the conveyors 201 to 204). .

  Here, in the example of FIG. 2, the shelf of each stage of the mounting shelf 132 has a left end lower than the right end, and the commodity positioned on the right side of the empty box according to the empty box being paid out. The box shifts to the left due to gravity. For this reason, a product box is always placed on the left end of each shelf of the placement shelf 132.

  FIG. 3 is a top view showing the configuration of the storage system. As shown in FIG. 3, the conveyors 201 to 205, which are first transport devices, are straight along a plurality of product boxes arranged in the x-axis direction (first direction) at the end of each stage shelf. The container (for example, container 250) is conveyed in the x-axis direction.

  Moreover, the conveyors 210 and 310 which are 2nd conveying apparatuses are installed along the edge part position of the conveyors 202-204 which are 1st conveying apparatuses. In this way, the first transfer device (conveyors 201 to 205) and the second transfer device (conveyors 210 and 310) are installed in different directions, so that each of the first transfer devices, Containers can be exchanged with each transport device. Then, by combining the transport in the x-axis direction by the first transport device and the transport in the y-axis direction by the second transport device, according to the storage system 130, the container (for example, the container 250) is moved to the arrow 321. It becomes possible to carry according to. That is, according to the storage system 130, the container can be transported to an arbitrary position corresponding to a plurality of product boxes arranged in the x-axis direction at the end of each shelf.

  As shown in FIG. 3, the camera units 221 to 224 move in the x-axis direction in the vicinity (upper side) of a plurality of product boxes arranged in the x-axis direction at the end of each shelf. Similarly, the robot unit 231 moves in the x-axis direction in the vicinity (upper side) of a plurality of product boxes arranged in the x-axis direction at the end of each shelf. In each stage, the camera units 221 to 224 and the robot units 231 to 234 can move and stop independently of each other.

  However, in each stage, it is assumed that the movement ranges of the camera units 221 to 224 and the robot units 231 to 234 are substantially the same. For example, the first-stage camera unit 221 and the robot unit 231 move within the range indicated by the arrow 331, respectively. In addition, the second-stage camera unit 222 and the robot unit 232 move within the range indicated by the arrow 332, respectively. The camera unit 223 and the robot unit 233 in the third stage move within the range indicated by the arrow 333, respectively. Further, the camera unit 224 and the robot unit 234 in the fourth stage move within a range indicated by an arrow 334, respectively.

  FIG. 4 is a front view showing the configuration of the storage system. In the example of FIG. 4, eight product boxes in which different types of products are stuffed are arranged on each shelf. For this reason, according to the storage system 130, 32 types of products can be stored in the container 250 by transporting the container 250 to all the stages.

  Thus, even when the types of products stored in the container increase, the storage system 130 can effectively use the space in the height direction. In the storage system 130, the camera unit and the robot unit move between a plurality of product boxes at each stage. Furthermore, a transport device for placing the product box on the end of each shelf is not necessary. For this reason, in the case of the storage system 130, the installation space can be significantly reduced as compared with the case where the product boxes are arranged in a row and the picking device is installed for each product box as in the past.

<Hardware configuration of control device>
Next, the hardware configuration of the control device 131 of the storage system 130 will be described. FIG. 5 is a diagram illustrating an example of a hardware configuration of the control device.

  As illustrated in FIG. 5, the control device 131 includes a CPU (Central Processing Unit) 501, a ROM (Read Only Memory) 502, and a RAM (Random Access Memory) 503. The CPU 501, the ROM 502, and the RAM 503 form a so-called computer. The control device 131 includes an auxiliary storage device 504, an I / F (Interface) device 505, an operation device 506, a display device 507, and a drive device 508. The hardware of the control device 131 is connected to each other via a bus 509.

  The CPU 501 executes various programs installed in the auxiliary storage device 504. The ROM 502 is a non-volatile memory and functions as a main storage device. The ROM 502 stores various programs, data, and the like necessary for the CPU 501 to execute various programs installed in the auxiliary storage device 504. Specifically, the ROM 502 stores a boot program such as BIOS (Basic Input / Output System) and EFI (Extensible Firmware Interface).

  The RAM 503 is a volatile memory such as a DRAM (Dynamic Random Access Memory) or an SRAM (Static Random Access Memory), and functions as a main storage device. The RAM 503 provides a work area that is expanded when various programs installed in the auxiliary storage device 504 are executed by the CPU 501.

  The auxiliary storage device 504 stores various programs and information used when the various programs are executed by the CPU 501.

  The I / F device 505 is a connection device that connects to the overall computer 110, the transport device 133 in the storage system 130, and the picking device 134. The operation device 506 is an input device for the operator 260 to input various instructions to the control device 131. The display device 507 is a display device that displays the display screen generated by the control device 131.

  The drive device 508 is a device for setting the recording medium 510. The recording medium 510 here includes a medium for recording information optically, electrically, or magnetically, such as a CD-ROM, a flexible disk, a magneto-optical disk, or the like. Further, the recording medium 510 may include a semiconductor memory that electrically records information, such as a ROM and a flash memory.

  The various programs installed in the auxiliary storage device 504 are installed by, for example, setting the distributed recording medium 510 in the drive device 508 and reading out the various programs recorded in the recording medium 510 by the drive device 508. Is done.

<Functional configuration of storage system>
Next, the functional configuration of the storage system 130 will be described. FIG. 6 is a diagram illustrating an example of a functional configuration of the storage system according to the first embodiment. As shown in FIG. 6, in the storage system 130, the control device 131 functions as a conveyor control unit 601 and a robot movable control unit 602 by executing various programs installed in the auxiliary storage device 504. Further, the control device 131 functions as a camera movement control unit 603, a picking control unit 604, a camera control unit 605, and an empty box payout control unit 606.

  The overall control unit 600 receives information on the product boxes stored in the product storage area 120, information on the delivery destination of the containers delivered in the delivery area 150, and the like from the central computer 110, and creates a storage plan for each lot. Generate. The storage plan generated by the overall control unit 600 includes data that associates each store of the delivery destination with the type and quantity of the product stored in the container of each store (hereinafter referred to as “picking instruction data”). Is included.

  The overall control unit 600 functions as a registration unit. Specifically, the overall control unit 600 includes information (hereinafter referred to as “replenishment information”) about the product box placed by the worker 260 at each placement position (location) of each shelf of the placement shelf 132. Registration) is received, and the received supplement information is stored in the supplement information storage unit 610.

  When the conveyor control unit 601 acquires picking instruction data from the overall control unit 600, the conveyor control unit 601 refers to the supplement information stored in the supplement information storage unit 610. Further, the conveyor control unit 601 determines a stop position and a stop order of containers when picking up a product based on the reference result, and generates picking order information. Furthermore, the conveyor control unit 601 transmits the generated picking order information to the transport device 133. Thereby, in the conveyors 201 to 205, 210, and 310, conveyance and stop according to picking order information can be realized.

  When the robot movement control unit 602 acquires picking instruction data from the overall control unit 600, the robot movement control unit 602 refers to the supplement information stored in the supplement information storage unit 610. Also, the robot movement control unit 602 determines the order in which the robot units 231 to 234 of each stage are moved within the range indicated by the arrows 331 to 334 based on the reference result, and generates robot movement order information. Further, the robot movement control unit 602 transmits the generated robot movement order information to the robot movement mechanism unit 621 in the picking device 134. Thereby, in the robot movable mechanism part 621, the movement of the robot parts 231 to 234 according to the robot movable order information can be realized.

  When the camera movement control unit 603 acquires picking instruction data from the overall control unit 600, the camera movement control unit 603 refers to the supplement information stored in the supplement information storage unit 610. Further, the camera movement control unit 603 determines the order for moving the camera units 221 to 224 of each stage within the range indicated by the arrows 331 to 334 based on the reference result, and generates camera movement order information. Further, the camera movement control unit 603 transmits the generated camera movement order information to the camera movement mechanism unit 622 in the picking device 134. Thereby, in the camera movable mechanism part 622, the movement of the camera parts 221-224 according to camera movable order information is realizable.

  The picking control unit 604 acquires picking instruction data from the overall control unit 600, and specifies the product and quantity to be picked. In addition, the picking control unit 604 acquires product box image information from the camera control unit 605. Then, the picking control unit 604 generates information (removal information) necessary for each of the robot units 231 to 234 to take out the specified quantity of products from the product box. In addition, the picking control unit 604 acquires in-container image information from the camera control unit 605, and each robot unit 231 to 234 generates information (storage information) necessary when storing products in the container. Further, the picking control unit 604 transmits the generated extraction information and storage information to the robot units 231 to 234 in the picking device 134. Thereby, in the robot parts 231 to 234, it is possible to realize the take-out of the product and the storage of the product according to the take-out information and the storage information.

  Each of the robot units 231 to 234 has a hand for taking out the product and storing it in a container, and a distance sensor for measuring a distance to the product.

  The camera control unit 605 acquires the image information in the product box obtained by photographing the inside of the product box by each of the camera units 221 to 224 and the image information in the container obtained by photographing the inside of the container, and performs picking control. To the unit 604 and the empty box payout control unit 606.

  The empty box payout control unit 606 acquires the image information in the product box from the camera control unit 605, and generates a payout instruction for paying out the empty box. In addition, the empty box payout control unit 606 transmits the generated payout instruction to any of the robot units 231 to 234 in the picking device 134. Thereby, one of the robot units 231 to 234 pays out the corresponding empty box in response to the payout instruction.

<Details of supplementary information>
Next, details of the supplement information stored in the supplement information storage unit 610 will be described. As described above, the replenishment information is information on each product box placed by the worker 260 at each placement position (location) of each shelf of the placement shelf 132. FIG. 7 is a diagram illustrating an example of the supplement information.

  As shown in FIG. 7, the supplement information 700 includes “number of columns” and “number of stages” for specifying the location as information items. As shown in FIG. 4, in the case of the storage system 130, since eight product boxes are arranged in the x-axis direction, numerical values of 1 to 8 are stored in “number of columns”. Further, in the case of the storage system 130, since the product boxes are arranged in four stages in the z-axis direction, a numerical value of 1 to 4 is stored in the “number of stages”.

  As shown in FIG. 7, in the case of the supplement information 700, the area specified by the “number of columns” and the “number of stages” is packed in the location number of the area and the product box placed in the area. A product number indicating the product and the quantity of the product are registered.

  In the example of FIG. 7, location number = “4-1”, product number = “D1”, quantity in the area specified by “number of columns” = “1” and “number of columns” = “4” in the supplement information 700. = "100" is registered. Further, in the example of FIG. 7, an area specified by “number of columns” = “8” and “number of stages” = 1 ”in the supplement information 700 includes location number =“ 1-8 ”, product number =“ A8 ”, This indicates that the quantity = “150” is registered.

<Details of conveyor control unit>
Next, details of the conveyor control unit 601 of the control device 131 will be described.

(1) Functional configuration of conveyor control unit First, the functional configuration of the conveyor control unit 601 will be described. FIG. 8 is a diagram illustrating an example of a functional configuration of the conveyor control unit. As illustrated in FIG. 8, the conveyor control unit 601 includes an instruction acquisition unit 801, a supplement information reading unit 802, and a picking order determination unit 803.

  The instruction acquisition unit 801 acquires picking instruction data from the overall control unit 600 and notifies the picking order determination unit. The picking instruction data 810 in FIG. 8 is an example of picking instruction data acquired by the instruction acquisition unit 801 from the overall control unit 600. As shown in FIG. 8, the picking instruction data 810 includes “store ID”, “product number”, and “product quantity” as information items. Thereby, in the instruction | indication acquisition part 801, the kind and quantity of goods stored in the container of each store can be specified.

  The supplement information reading unit 802 reads supplement information 700 from the supplement information storage unit 610 and notifies the picking order determination unit 803 of the supplement information 700.

  Based on the picking instruction data 810 and the replenishment information 700, the picking order determination unit 803 determines a stop position and a stop order of containers when picking a product, and generates picking order information. Also, the picking order determination unit 803 transmits the generated picking order information to the transport device 133. The picking order information 820 in FIG. 8 is an example of picking order information generated by the picking order determining unit 803.

  As shown in FIG. 8, the picking order information 820 includes “shop ID”, “product number”, “location number”, and “picking order” as information items. According to the example of FIG. 8, when each product is stored in the container of “store ID” = “01”, the product is first placed at the placement position of “location number” = “1-5”. The product with “product number” = “A5” is taken out from the product box. Second, the product with “product number” = “B8” is taken out from the product box placed at the placement position with “location number” = “2-8”. Thereafter, the product is extracted according to the picking order information 820, and finally, the product of “product number” = D1 ”is extracted from the product box placed at the placement position of“ location number ”=“ 4-1 ”. The transport device 133 transports and stops the container so that the product can be taken out according to the picking order information 820.

(2) Operation Example of Conveying Device Next, an operation example of the conveying device 133 for realizing container transportation and stop according to the picking order information 820 generated by the conveyor control unit 601 will be described.

  FIG. 9 is a diagram illustrating an operation example of the transport device. As illustrated in FIG. 9, the conveyors 201 to 205, 210, and 310 included in the transport device 133 control the transport of the container 250 based on the picking order information 820. Thereby, the conveyors 201 to 205, 210, and 310 included in the transport device 133 transport the container 250 along the arrow. In addition, the conveyors 201 to 204 included in the transport device 133 control the stop of the container 250 based on the picking order information 820. As a result, the conveyors 201 to 204 have positions corresponding to the product boxes in which the products to be taken out are packed (in the example of FIG. 9, “product number” = “A5”, “B8”, “B3”, “C1”, The container 250 is stopped at “C5”, “D6”, “D3”, “D1”).

(3) Transfer Control Processing by Transfer Device Next, a flow of transfer control processing by the transfer device 133 will be described. FIG. 10 is a flowchart illustrating a flow of a conveyance control process by the conveyance device. As shown in FIG. 10A, in step S1001, the transport device 133 acquires picking order information (for example, picking order information 820) from the conveyor control unit 601.

  In step S1002, the transport device 133 generates a transport sequence for realizing transport and stop according to the picking order information. The transport sequence generated by the transport device 133 includes the transport sequences of the conveyors 201 to 204, 210, and 310.

  In step S1003, the transport device 133 determines whether an operation start instruction has been received. If it is determined in step S1003 that an operation start instruction has not been received (NO in step S1003), the process waits until an operation start instruction is received.

  On the other hand, if it is determined in step S1003 that an operation start instruction has been received (YES in step S1003), the process proceeds to step S1004. In step S <b> 1004, the transport device 133 executes transport and stop processing for the conveyors 201 to 204, 210, and 310. Details of the conveyance and stop processing in step S1004 will be described later.

  In step S <b> 1005, the transport device 133 determines whether or not picking has been completed for the containers of all stores included in the picking order information. If it is determined in step S1005 that there is a container that has not been picked yet (NO in step S1005), the process returns to step S1004. On the other hand, if it is determined in step S1005 that the storage of the product has been completed for all the containers of the stores included in the picking order information 820 (in the case of YES in step S1005), the conveyance control process is terminated. To do.

  FIG. 10B is a flowchart showing details of the transfer and stop processing in step S1004, and shows the flow of transfer and stop processing for any one of the conveyors (here, the conveyor 201).

  As shown in FIG. 10B, in step S1011, the conveyor 201 determines whether or not a conveyance instruction has been received. For example, when the conveyor 201 receives a notification indicating that picking is being performed from the robot unit 231, the conveyor 201 determines that a conveyance instruction has not been received (NO in step S <b> 1011), and waits until a conveyance instruction is received.

  Further, in the conveyor 201, for example, when a notification that the picking is completed is received from the robot unit 231, it is determined that a conveyance instruction has been received (YES in step S1011), and the process proceeds to step S1012.

  In step S1012, the conveyor 201 starts conveyance. In step S <b> 1013, the conveyor 201 determines whether there is a product that the robot unit 231 intends to pick next in the same stage.

  If it is determined in step S1013 that there is an item to be picked next (YES in step S1013), the process proceeds to step S1014. In step S1014, the conveyor 201 stops the conveyance at a position corresponding to the placement position of the commodity box of the commodity to be picked next according to the conveyance sequence, and returns to step S1011. On the other hand, if it is determined in step S1013 that there is no next product to be picked (NO in step S1013), the process proceeds to step S1015.

  In step S <b> 1015, the conveyor 201 conveys the container currently being conveyed to the position of the conveyor 210, and delivers the container to the conveyor 210. Thereafter, the process returns to step S1005 in FIG. 10A, and if there is a next container, the same process (step S1004) is performed.

<Details of robot movement control unit>
Next, details of the robot movement control unit 602 of the control device 131 will be described.

(1) Functional Configuration of Robot Movement Control Unit First, a functional configuration of the robot movement control unit 602 will be described. FIG. 11 is a diagram illustrating an example of a functional configuration of the robot movement control unit. As illustrated in FIG. 11, the robot movement control unit 602 includes an instruction acquisition unit 1101, a supplementary information reading unit 1102, and a robot movement order determination unit 1103.

  The instruction acquisition unit 1101 acquires picking instruction data from the overall control unit 600 and notifies the robot movable order determination unit 1103 of the picking instruction data. The picking instruction data 1110 in FIG. 11 is an example of picking instruction data that the instruction acquiring unit 1101 acquires from the overall control unit 600. As shown in FIG. 11, the picking instruction data 1110 includes “store ID” and “product number” as information items. Thereby, in the instruction | indication acquisition part 1101, each robot part 231-234 can specify the goods which should be accommodated in the container of each store.

  According to the example of FIG. 11, the robot unit 231 stores the products with the product numbers = “A1” and “A8” in the container of the store with the store ID = “01”. Further, the robot unit 231 stores the products with the product numbers = “A3” and “A5” in the store container with the store ID = “02”. Further, the robot unit 231 stores the product with the product number = “A1” in the container of the store with the store ID = “03”.

  The replenishment information reading unit 1102 reads the replenishment information 700 from the replenishment information storage unit 610 and notifies the robot movable order determination unit 1103 of it.

  Based on the picking instruction data 1110 and the replenishment information 700, the robot movable order determination unit 1103 determines the movement order of the robot unit 231 when storing the product in the container of each store, and determines the robot movable order information. Generate. The robot movable order information 1120 in FIG. 11 is an example of the robot movable order information generated by the robot movable order determining unit 1103 based on the picking instruction data 1110 and the supplement information 700.

  As shown in FIG. 11, the robot movable order information 1120 includes “store ID”, “product number”, “location number”, and “robot movable order” as information items. According to the example of FIG. 11, the robot unit 231 first moves to the placement position of “location number” = “1-1”. Further, the robot unit 231 moves to the placement position of “location number” = “1-8” second. Thereafter, the robot moves in accordance with the robot movement order information 1120, and finally moves to the placement position of “location number” = “1-1”.

(2) Operation Example of Robot Movement Mechanism Unit Next, an operation example of the robot movement mechanism unit 621 that realizes an operation according to the robot movement order information 1120 generated by the robot movement control unit 602 will be described.

  FIG. 12 is a diagram illustrating an operation example of the robot movable mechanism unit. As shown in FIG. 12A, among the mechanism units of each stage of the robot movable mechanism unit 621, the mechanism unit of the first stage is moved based on the robot movement order information 1120, so that the robot unit 231 is It can be moved to the position indicated by the arrow in FIG. 12B in the order indicated by the arrow.

(3) Robot Moving Process by Robot Moving Mechanism Unit Next, the flow of the robot moving process by the robot moving mechanism unit 621 will be described. FIG. 13 is a flowchart showing the flow of the robot moving process by the robot moving mechanism.

  As shown in FIG. 13A, in step S1301, the robot movable mechanism unit 621 acquires robot movable order information (for example, robot movable order information 1120) from the robot movable control unit 602.

  In step S1302, the robot movable mechanism unit 621 generates a robot movable sequence corresponding to the robot movable order information. It is assumed that the robot movement sequence generated by the robot movement mechanism unit 621 includes a robot movement sequence for each stage of the robot movement mechanism unit 621.

  In step S1303, the robot movable mechanism unit 621 determines whether an operation start instruction has been received. If it is determined in step S1303 that an operation start instruction has not been received (NO in step S1303), the process waits until an operation start instruction is received.

  On the other hand, if it is determined in step S1303 that an operation start instruction has been received (YES in step S1303), the process proceeds to step S1304. In step S1304, the mechanism units of each stage of the robot movable mechanism unit 621 execute the movement and stop processing of the robot units 231 to 234 of each stage. Details of the movement and stop processing in step S1304 will be described later.

  In step S1305, the robot movable mechanism unit 621 determines whether or not picking has been completed for the containers of all stores included in the robot movable order information. If it is determined in step S1305 that there is a container that has not been picked yet (in the case of NO in step S1305), the process returns to step S1304. On the other hand, if it is determined in step S1305 that picking has been completed for all the containers in the store included in the robot movement order information (YES in step S1305), the robot movement process is terminated.

  FIG. 13B is a flowchart showing details of the movement and stop processing in step S1304. The movement and movement of the robot unit 231 by any one of the mechanism units (here, the first-stage mechanism unit) The flow of stop processing is shown.

  As illustrated in FIG. 13B, in step S1311, the first-stage mechanism unit determines whether a movement instruction has been received. For example, when the mechanism unit at the first stage receives a notification from the robot unit 231 that picking is being performed, it determines that the movement instruction has not been received (NO in step S1311), and waits until the movement instruction is received. To do.

  Further, in the first stage mechanism unit, for example, when a notification to the effect that picking has been completed is received from the robot unit 231, it is determined that a movement instruction has been received (YES in step S1311), and the process proceeds to step S1312.

  In step S1312, the first-stage mechanism unit starts moving the robot unit 231. In step S1313, the first-stage mechanism unit stops the movement of the robot unit 231 according to the robot movement sequence. Thereafter, the process returns to step S1305 in FIG. 13A, and if there is a next container, the same processing (step S1304) is performed.

<Details of camera movement control unit>
Next, details of the camera movement control unit 603 of the control device 131 will be described.

(1) Functional Configuration of Camera Movement Control Unit First, a functional configuration of the camera movement control unit 603 will be described. FIG. 14 is a diagram illustrating an example of a functional configuration of the camera movement control unit. As illustrated in FIG. 14, the camera movement control unit 603 includes an instruction acquisition unit 1401, a supplement information reading unit 1402, and a camera movement order determination unit 1403.

  The instruction acquisition unit 1401 acquires picking instruction data from the overall control unit 600 and notifies the camera movable order determination unit 1403 of the picking instruction data. The picking instruction data 1110 in FIG. 14 is an example of picking instruction data that the instruction acquisition unit 1401 acquires from the overall control unit 600. As shown in FIG. 14, the picking instruction data 1110 acquired by the instruction acquisition unit 1401 is the same as the picking instruction data acquired by the instruction acquisition unit 1101 of the robot movement control unit 602. Thereby, in the instruction | indication acquisition part 1401, each robot part 231-234 can specify the goods which should be accommodated in the container of each store (that is, the camera part 221-224 specifies the product box which should be image | photographed. Can do).

  According to the example of FIG. 14, the robot unit 231 stores the products with the product numbers = “A1” and “A8” in the container of the store with the store ID = “01”. Further, the robot unit 231 stores the products with the product numbers = “A3” and “A5” in the store container with the store ID = “02”. Further, the robot unit 231 stores the product with the product number = “A1” in the container of the store with the store ID = “03”.

  The supplement information reading unit 1402 reads the supplement information 700 from the supplement information storage unit 610 and notifies the camera movable order determination unit 1403 of the supplement information 700.

  Based on the picking instruction data 1110 and the replenishment information 700, the camera movable order determination unit 1403 determines the movement order of the camera unit 221 when storing the product in the container of each store, and sets the camera movable order information. Generate. Camera movable order information 1420 in FIG. 14 is an example of camera movable order information generated by the camera movable order determination unit 1403 based on the picking instruction data 1110 and the supplement information 700.

  As shown in FIG. 14, the camera movable order information 1420 includes “store ID”, “product number”, “location number”, and “camera movable order” as information items. According to the example of FIG. 14, the camera unit 221 moves first to the placement position of “location number” = “1-1”, and places it on the placement position of “location number” = “1-1”. Take a picture of the product box.

  Further, according to the example of FIG. 14, the camera unit 221 moves secondly to the placement position of “location number” = “1-8”, and places “location number” = “1-8”. The inside of the product box placed at the position is photographed.

  Thereafter, the camera unit 221 moves according to the camera movable order information 1420, and finally moves to the placement position of “location number” = “1-1”.

(2) Operation Example of Camera Movement Mechanism Unit Next, an operation example of the camera movement mechanism unit 622 that realizes an operation corresponding to the camera movement order information 1420 generated by the camera movement control unit 603 will be described.

  FIG. 15 is a diagram illustrating an operation example of the camera movable mechanism unit. As shown in FIG. 15 (a), the first stage mechanism section moves based on the camera movement order information 1420, as shown in FIG. It can be moved to the position indicated by the arrow in FIG. 15B in the order indicated by the arrow.

(3) Camera Movement Process by Camera Movement Mechanism Unit Next, the flow of the camera movement process by the camera movement mechanism unit 622 will be described. FIG. 16 is a flowchart showing the flow of the camera moving process by the camera moving mechanism.

  As shown in FIG. 16A, in step S1601, the camera movable mechanism unit 622 acquires camera movable order information (for example, camera movable order information 1420) from the camera movable control unit 603.

  In step S1602, the camera movable mechanism unit 622 generates a camera movable sequence corresponding to the camera movable order information. It is assumed that the camera movable sequence generated by the camera movable mechanism unit 622 includes the camera movable sequence of each stage of the camera movable mechanism unit 622.

  In step S1603, the camera movable mechanism unit 622 determines whether an operation start instruction has been received. If it is determined in step S1603 that an operation start instruction has not been received (NO in step S1603), the process waits until an operation start instruction is received.

  On the other hand, if it is determined in step S1603 that an operation start instruction has been received (YES in step S1603), the process proceeds to step S1604. In step S <b> 1604, the mechanism units of each stage of the camera movable mechanism unit 622 execute processing for moving and stopping the camera units 221 to 224 of each stage. Details of the movement and stop processing in step S1604 will be described later.

  In step S <b> 1605, the camera movable mechanism unit 622 determines whether picking has been completed for all store containers included in the camera movable order information. If it is determined in step S1605 that there is a container that has not been picked yet (NO in step S1605), the process returns to step S1604. On the other hand, if it is determined in step S1605 that picking has been completed for all store containers included in the camera movable order information (YES in step S1605), the camera movable process is terminated.

  FIG. 16B is a flowchart showing details of the movement and stop processing in step S1604, and the movement and movement of the camera unit 221 by any one of the mechanical units (here, the first mechanical unit). The flow of stop processing is shown.

  As illustrated in FIG. 16B, in step S1611, the first-stage mechanism unit determines whether a movement instruction has been received. For example, if the first-stage mechanism unit has not received a notification that preparation of a container to be picked next has been completed, it determines that a movement instruction has not been received (NO in step S1611), and the movement instruction is issued. Wait for reception.

  For example, when the first-stage mechanism unit receives a notification that the preparation of the container to be picked next is completed, it determines that a movement instruction has been received (YES in step S1611), and proceeds to step S1612.

  In step S <b> 1612, the first-stage mechanism unit starts moving the camera unit 221. In step S1613, the first-stage mechanism unit stops moving the camera unit 221 in accordance with the camera movement sequence. Thereafter, the process returns to step S1605 in FIG. 16A, and if there is a next container, the same processing (step S1604) is performed.

<Details of Picking Control Unit>
Next, details of the picking control unit 604 of the control device 131 will be described.

(1) Functional Configuration of Picking Control Unit First, a functional configuration of the picking control unit 604 will be described. FIG. 17 is a diagram illustrating an example of a functional configuration of the picking control unit. As illustrated in FIG. 17, the picking control unit 604 includes an image information acquisition unit 1701, an arrangement recognition unit 1702, a product height registration unit 1703, an instruction acquisition unit 1704, and a take-out order determination unit 1705. Further, the picking control unit 604 includes an image information acquisition unit 1711, an arrangement recognition unit 1712, and a storage position determination unit 1713.

  The image information acquisition unit 1701 acquires the image information (product box image information 1710) obtained by photographing the inside of the product box from the camera control unit 605 together with the location number. The arrangement recognition unit 1702 recognizes the arrangement of products in the product box based on the image information 1710 in the product box.

  The product height registration unit 1703 determines whether the product box of the product box image information 1710 is a product box of a product that is handled for the first time in the lot. The determination as to whether the product box is a product box that is handled for the first time in the lot is made based on an instruction from the operator 260, for example.

  In addition, when the product height registration unit 1703 determines that the product box is a product box of the product handled for the first time, the product box height information indicating the height of the side wall of the product box and the product packed in the product box before picking. Product height information (predetermined default value) indicating the height of the product is received. In the following, such a product is referred to as “first product in the product box”.

  Further, the product height registration unit 1703 notifies the robot unit of the product box height information and the product height information received as input information. The product height information (predetermined default value) registered in the product height registration unit 1703 is rewritten when the first product in the product box is picked (details will be described later). . When the product height information is rewritten, the product height registration unit 1703 notifies the robot unit of the rewritten product height information as take-out information and storage information.

  The instruction acquisition unit 1704 acquires picking instruction data from the overall control unit 600 and notifies the take-out order determination unit 1705 of the picking instruction data. The picking instruction data 1730 in FIG. 17 is an example of picking instruction data that the instruction acquisition unit 1704 acquires from the overall control unit 600.

  As shown in FIG. 17, the picking instruction data 1730 includes “store ID”, “product number”, and “product quantity” as information items. Thereby, in the instruction | indication acquisition part 1704, each robot part 231-234 can specify the goods and the quantity which should be accommodated in the container of each store.

  Based on the arrangement of the products in the product box recognized by the arrangement recognition unit 1702 and the quantity of the product specified by the instruction acquisition unit 1704, the take-out order determination unit 1705 and the products to be taken out from the product box The order of taking out the goods is determined. In addition, the take-out order determination unit 1705 notifies the robot unit of the product to be taken out from the product box and the order in which those products are taken out as take-out information.

  The image information acquisition unit 1711 acquires image information (in-container image information 1720) obtained by photographing the inside of the container from the camera control unit 605. The arrangement recognition unit 1712 recognizes the arrangement of products in the container based on the in-container image information 1720.

  The storage position determination unit 1713 determines an area for storing the product in the container based on the recognized arrangement of the product in the container. In addition, the storage position determination unit 1713 notifies the robot unit of the storage area of the product in the container as storage information.

(3) Robot unit operation example 1
Next, an operation example at the time of product take-out of the robot units 231 to 234 for realizing the operation according to the take-out information generated by the picking control unit 604 will be described. Here, an example of operation of the robot unit 231 when taking out a product will be described.

  FIG. 18 is a diagram illustrating an operation example of the robot unit when a product is taken out. Among these, FIG. 18A shows an example of information 1810 indicating the products to be taken out from the product box and the order of taking out the products out of the information for taking out notified from the picking control unit 604.

  In FIG. 18 (a), a product with a circled number indicates a product to be taken out from the product box. The circled numbers indicate the order in which those products are taken out.

  FIG. 18B shows an operation example of the take-out operation by the robot unit 231. As shown in FIG. 18B, the robot unit 231 includes a hand 1801 for taking out a product and a distance sensor 1802 for measuring the distance to the product.

In the robot unit 231, when the hand 1801 takes out the first product in the product box, first, the distance sensor 1802 measures the distance d to the first product in the product box. Subsequently, the robot unit 231, depending on the moving distance D _D from the hand 1801 is calculated based on the measured distance d to the first item in the product box to operate the hand 1801, 1 in item box Access the th item.

  As described above, the robot unit 231 causes the hand 1801 to access the product after measuring the distance to the product using the distance sensor 1802. As a result, the robot unit 231 can access the product 1801 at high speed without damaging the product.

Subsequently, the robot unit 231 causes the hand 1801 to lift the first product in the product box. At this time, the robot unit 231, among the extraction information notified from the picking control unit 604, based on the product box height information and the product height information, determines the height D _L lifted. Specifically, the robot unit 231 sets a value obtained by adding a fixed value to the sum of the product height information (predetermined default value H ₀ ) and the product box height information H _b as the lift height _DL . decide.

When the first product in the raised product box is stored in the container by the hand 1801 and the picking of the first product in the product box is completed, the product height information in the product height registration unit 1703 is displayed. Rewritten. For this reason, when the robot unit 231 causes the hand 1801 to lift the second product in the product box, the lifting height _DL is determined based on the product box height information and the rewritten product height information. . Specifically, the robot unit 231 raises a value obtained by adding a fixed value to the sum of the product height information (the product height information H _p after rewriting) and the product box height information H _b. It is determined to be D _L.

  Thus, the robot unit 231 controls the position of the product lifting height based on the product height information and the product box height information. Thereby, in the robot part 231, the lifting height of goods can be minimized, without damaging goods. As a result, the robot unit 231 can improve the efficiency of the operation when taking out the product.

(4) Robot unit operation example 2
Next, an operation example of the robot units 231 to 234 that realizes an operation according to the storage information generated by the picking control unit 604 will be described. Here, an example of the operation of the robot unit 231 when the product is stored will be described.

  FIG. 19 is a diagram illustrating an operation example when the robot unit stores products. Among these, FIG. 19A shows an example of storage information (information indicating a region in which a product is stored in the container) notified from the picking control unit 604.

  In FIG. 19A, an area 1901 indicates an area for storing products in the container. FIG. 19B shows an operation example of the storing operation by the robot unit 231.

  In the robot unit 231, when storing the product taken out by the hand 1801 in the container, first, the distance sensor 1802 measures the distance d to the area 1901 and calculates the height information of the area 1901. Subsequently, the robot unit 231 accesses the area 1901 at a low speed so as not to damage the product during storage, and releases the product when the bottom surface of the product contacts the area 1901. At this time, the robot unit 231 acquires the height information of the hand 1801 (that is, the height information of the upper surface of the product), and the product height information (predetermined default value) from the difference value with the height information of the area 1901 Is calculated and registered as master data. Thereby, the product height information registered in the product height registration unit 1703 is rewritten.

Subsequently, in storing the next product of the same type, the robot unit 231 has a position in the height direction specified by the sum value of the height information of the area 1901 and the rewritten product height information. to move the hand 1801, and calculates the moving distance _{D D} hand 1801. That is, the robot unit 231 controls the position in the height direction where the hand 1801 separates the product based on the height information of the area 1901 and the rewritten product height information.

  Thereby, in the robot part 231, the hand 1801 can be moved to the position of the height direction which leaves | separates goods at high speed. That is, the robot unit 231 can increase the moving speed when storing the product without damaging the product. As a result, the robot unit 231 can improve the efficiency of the operation when storing the product.

(5) Robot control processing 1 by the robot unit
Next, the flow of robot control processing (removal) by the robot units 231 to 234 will be described. FIG. 20 is a flowchart showing the flow of robot control processing (removal) by the robot unit. Here, the robot unit 231 stores “product number” = “A2” products, “product quantity” = “8” pieces, product box in order for the robot unit 231 to store them in the container of “store ID” = “01”. A robot control process in the case of taking out from will be described.

  As shown in FIG. 20A, in step S2001, the product height registration unit 1703 of the picking control unit 604 determines that the target product (product with “product number” = “A2”) is 1 in the product box. It is determined whether it is the th product. If it is determined that the target product is the same type of product as the product already picked by the robot unit 231 (NO in step S2001), the process proceeds to step S2003.

  On the other hand, when it is determined that the target product is the first product in the product box (YES in step S2001), the process proceeds to step S2002. In step S2002, the product height registration unit 1703 of the picking control unit 604 executes master data registration processing (master registration processing) at the time of taking out the product.

  In step S2003, the robot unit 231 executes a take-out process. In step S2004, the robot unit 231 determines whether picking has been completed for the target product. Specifically, the robot unit 231 stores “product number” = “A2” products, “product quantity” = “8”, and product boxes in order to store them in a container of “store ID” = “01”. It is determined whether or not it has been taken out from.

  If it is determined in step S2004 that picking has not been completed for the target product (NO in step S2004), the process returns to step S2003. On the other hand, if it is determined in step S2004 that picking has been completed for the target product (YES in step S2004), the robot control process (removal) is terminated. Specifically, the robot control processing (removal) for the product (“product number” = “A2” product) for the container (“store ID” = “01” container) is terminated.

  FIG. 20B is a flowchart showing details of the master registration process in step S2002. As shown in FIG. 20B, in step S2011, the product height registration unit 1703 of the picking control unit 604 acquires height information (product box height information and product height information (default value)).

  In step S2012, the product height registration unit 1703 of the picking control unit 604 registers the height information and notifies the robot unit 231 of the registered height information as extraction information.

  FIG. 20C is a flowchart showing details of the extraction process in step S2003. In step S2021, the robot unit 231 acquires take-out information (product box height information, product height information (default or after rewriting), products to be taken out from the product box, and the order in which those products are taken out).

In step S2022, the robot unit 231 causes the hand 1801 to access a product (a product having “product number” = “A2”). In step S2023, the robot 231 lifts calculates the height _{D L,} the hand 1801, causing lift the (items "Product ID" = "A2") Product height _{D L} lifting was calculated.

  In step S2024, the robot unit 231 horizontally moves the hand 1801 to the position of the corresponding container (“store ID” = “01” container).

(6) Robot control processing 2 by the robot unit
Next, a flow of robot control processing (storage) by the robot units 231 to 234 will be described. FIG. 21 is a flowchart showing a flow of robot control processing (storage) by the robot unit. Here, the robot controller 231 controls the robot when storing “product number” = “8” pieces of “product number” = “A2” in the container of “store ID” = “01”. Processing will be described.

  As shown in FIG. 21 (a), in step S2101, the product height registration unit 1703 of the picking control unit 604 determines that the target product (product of “product number” = “A2”) is 1 in the product box. It is determined whether it is the th product. If the target product type is determined to be the same type of product as the product already picked by the robot unit 231 (NO in step S2101), the process proceeds to step S2103.

  On the other hand, if it is determined that the target product is the first product in the product box (YES in step S2101), the process proceeds to step S2102. In step S2102, the product height registration unit 1703 of the picking control unit 604 executes master data registration processing (master registration processing) when storing the product, and the process proceeds to step S2104.

  In step S2103, the robot unit 231 executes storage processing. In step S2104, the robot unit 231 determines whether or not picking has been completed for the target product. Specifically, the robot unit 231 determines whether or not “product quantity” = “8” items of “product number” = “A2” are stored in the container of “store ID” = “01”. judge.

  If it is determined in step S2104 that picking has not been completed for the target product (NO in step S2104), the process returns to step S2101. On the other hand, if it is determined in step S2104 that picking has been completed for the target product (YES in step S2104), the robot control process (storage) is terminated. Specifically, the robot control processing (storage) is finished for the product (product of “product number” = “A2”) for the container (“store ID” = “01” container).

  FIG. 21B is a flowchart showing details of the master registration process in step S2101. The robot unit 231 horizontally moves the hand 1801 in the take-out process (step S2024 in FIG. 20C), and then in step S2111 in FIG. 21B, the container (“store ID” = “01” container). Stop at the position of.

  In step S2112, the robot unit 231 acquires storage information (information indicating a region in which a product is stored in the container). In step S2113, the robot unit 231 measures the height information of the storage area using the distance sensor 1802, and then moves the hand 1801 to the area at a low speed to store the product.

  In step S2114, the robot unit 231 calculates the product height information by calculating a difference value between the area height information and the hand 1801 height information when storing the product.

  In step S2115, the product height registration unit 1703 of the picking control unit 604 registers the product height information calculated by the robot unit 231 as master data. Thereby, the product height information (predetermined default value) registered in the product height registration unit 1703 is rewritten.

  FIG. 21C is a flowchart showing details of the storage process in step S2103. In step S2121, the robot unit 231 horizontally moves the hand 1801 in step S2024 of the take-out process (FIG. 20C), and then in step S2121, the position of the container (“store ID” = “01” container). Stop at.

  In step S2122, the robot unit 231 acquires storage information (information indicating a region in which a product is stored in the container, product height information after rewriting). In step S <b> 2123, the robot unit 231 measures the height information of the area to be stored, and calculates the position in the height direction where the product is released by adding the product height information after rewriting. Further, the robot unit 231 calculates the movement distance of the hand 1801 based on the calculated position in the height direction, and stores the product by moving the hand 1801 at a high speed by the calculated movement distance.

<Details of empty box delivery control unit>
Next, details of the empty box delivery control unit 606 of the control device 131 will be described.

(1) Functional Configuration of Empty Box Delivery Control Unit First, a functional configuration of the empty box delivery control unit 606 will be described. FIG. 22 is a diagram illustrating an example of a functional configuration of the empty box payout control unit. As illustrated in FIG. 22, the empty box payout control unit 606 includes an image information acquisition unit 2201, an empty box identification unit 2202, and a conveyance control unit 2203.

  The image information acquisition unit 2201 acquires image information (image information in the product box 2200) obtained by photographing the inside of the product box from the camera control unit 605 together with the location number.

  The empty box specifying unit 2202 determines whether or not the product in the product box has become empty based on the image information 2200 in the product box. When the empty box specifying unit 2202 determines that the product in the product box is empty, the empty box specifying unit 2202 notifies the robot unit that takes out the product from the product box as a payout instruction. Thereby, in the robot part, the said merchandise box can be paid out toward a corresponding conveyor.

  If the empty box specifying unit 2202 determines that the product in the product box is empty, the transport control unit 2203 notifies the transport device 133 of the location number of the product box as a transport instruction. Thereby, in the conveying apparatus 133, a conveyance sequence is changed and the empty box paid out to the conveyor is conveyed to a predetermined position.

(2) Operation Example of Robot Unit Next, an operation example of the robot units 231 to 234 when a payout instruction is notified from the empty box payout control unit 606 will be described. Here, an operation example of the robot unit 231 will be described.

  FIG. 23 is a diagram illustrating an operation example of the robot unit when paying out an empty box. 23, when the robot unit 231 receives a payout instruction from the empty box payout control unit 606, the robot unit 231 moves to the position of the product box corresponding to the location number. Further, the robot unit 231 moves the empty box in the arrow 2302 direction by lowering the hand 1801 and then moving the hand 1801 in the arrow 2301 direction. As a result, the robot unit 231 can pay out empty boxes to the conveyor 201.

(3) Example of Operation of Conveying Device Next, an example of the operation of the conveying device 133 when a conveyance instruction is notified from the empty box dispensing control unit 606 will be described. FIG. 24 is a diagram illustrating an operation example of the transport device when the empty box is paid out.

  When the transport device 133 receives a transport instruction from the empty box delivery control unit 606, the transport device 133 changes the transport sequence for the conveyors 210 and 310. On the other hand, the transport sequence of the conveyors 201 to 205 is left as it is, and the transport device 133 transports the empty box 2400 as the container (for example, the container 250) is transported.

  In FIG. 24, an arrow 321 indicates the conveyance path of the container 250. On the other hand, an arrow 2401 indicates the conveyance path of the empty box 2400. As shown in FIG. 24, in the transport device 133, when the empty box 2400 is transported to the right end portion of the conveyor 201 as the container 250 is transported, it is delivered to the conveyor 210 and the conveyor 210 is transported to the upper end portion.

  Thereby, in the conveying apparatus 133, the empty box 2400 can be conveyed to the upper end part of the conveyor 210 by the shortest path.

(4) Empty Box Dispensing Process by Robot Unit Next, the flow of the empty box dispensing process by the robot unit will be described. FIG. 25 is a flowchart showing the flow of empty box payout processing by the robot unit. In step S2501, the robot units 231 to 234 determine whether a payout instruction has been received from the empty box payout control unit 606.

  If it is determined in step S2501 that a payout instruction has not been received (NO in step S2501), the process waits until a payout instruction is received. On the other hand, if it is determined in step S2501 that a payout instruction has been received (YES in step S2501), the process proceeds to step S2502.

  In step S2502, the robot units 231 to 234 determine whether or not empty boxes can be paid out. When there is a container at the position on the conveyor corresponding to the empty box, the robot units 231 to 234 determine that the payout is impossible (NO in step S2502), and wait until the payout becomes possible.

  On the other hand, if there is no container at the position on the conveyor corresponding to the empty box, the robot units 231 to 234 determine that the payout is possible (YES in step S2502), and proceed to step S2503.

  In step S2503, the robot units 231 to 234 move to the empty box position. In step S2504, the robot units 231 to 234 pay out empty boxes onto the conveyors 201 to 204.

  In step S2505, the robot units 231 to 234 determine whether or not the picking of the product has been completed for the containers of all stores included in the lot. If it is determined in step S2505 that there is a container for which picking of goods has not yet been completed (NO in step S2505), the process returns to step S2501. On the other hand, if it is determined in step S2505 that the picking of the product has been completed for the containers of all stores included in the lot (YES in step S2505), the empty box payout process is terminated.

As apparent from the above description, the storage system 130 according to the first embodiment is
A shelf in which a plurality of product boxes packed with different types of products is arranged in the x-axis direction has a mounting shelf 132 formed in a step shape in the y-axis direction.
-It has the conveyors 201-204 which are each installed along the some merchandise box arranged in each step, and convey a container to a x-axis direction.
-It has the conveyors 210 and 310 which are installed along the edge part position of each conveyor 201-204, give and receive a container between each conveyor 201-204, and convey a container in a y-axis direction.
Each of the stages has a picking device 134 that takes out and stores a product from a corresponding product box in a container transported to a predetermined position.
-A container is conveyed to a predetermined | prescribed position by combining conveyance of the x-axis direction by the conveyors 201-204 and conveyance of the y-axis direction by the conveyors 210 and 310. FIG.

  Thereby, according to the storage system 130 which concerns on 1st Embodiment, it becomes possible to use effectively the space of a height direction and can reduce the installation space of a system.

In addition, the storage system 130 according to the first embodiment includes:
When the picking device 134 takes out the product from the product box, the position of the product lifting height is controlled based on the height information of the side wall of the product box and the height information of the product.
When the picking device 134 stores the product in the container, the position in the height direction where the hand separates the product is controlled based on the height information of the storage area and the height information of the product.

  Thereby, according to the storage system 130 which concerns on 1st Embodiment, when taking out goods from a goods box, while raising height can be minimized, moving speed can be raised when storing in a container. As a result, in the storage system 130, the operation of the picking device can be made efficient.

[Second Embodiment]
In the first embodiment described above, the picking control unit 604 automatically determines the products to be taken out from the product box and the order in which those products are taken out. However, when the products are diversified, it is considered difficult to accurately recognize the arrangement of the products based on the image information in the product box. Therefore, in the second embodiment, the operator 260 can manually set the products to be taken out from the product box and the order in which those products are taken out. Hereinafter, the second embodiment will be described focusing on differences from the first embodiment.

<Functional configuration of storage system>
First, the functional configuration of the storage system according to the second embodiment will be described. FIG. 26 is a diagram illustrating an example of a functional configuration of the storage system according to the second embodiment. A difference from the storage system 130 described with reference to FIG. 6 is that the control device 131 includes a storage control unit 2601 and a remote control unit 2602 in the case of the storage system 2600 shown in FIG.

  The storage control unit 2601 has a function (image information acquisition unit 1711, arrangement recognition unit 1712, storage position determination unit 1713) related to generation of storage information in the picking control unit 604 of FIG. Since the image information acquisition unit 1711, the arrangement recognition unit 1712, and the storage position determination unit 1713 have already been described, description thereof is omitted here.

  The remote control unit 2602 acquires picking instruction data from the overall control unit 600 and identifies the product and quantity to be picked. In addition, the remote control unit 2602 acquires product box image information from the camera control unit 605. Further, the remote control unit 2602 displays the image information in the product box on the display device 507 together with the specified product and quantity, and designates the product to be taken out and the order for taking out those products. Accept from 260.

  Furthermore, the remote control unit 2602 notifies the robot units 231 to 234 of the designation about the products to be taken out and the designation about the order of taking out those products received from the worker 260 as the information for taking out.

<Details of remote control unit>
Next, details of the remote control unit 2602 of the control device 131 will be described.

(1) Functional Configuration of Remote Control Unit First, the functional configuration of the remote control unit 2602 will be described. FIG. 27 is a first diagram illustrating an example of a functional configuration of the remote control unit. As illustrated in FIG. 27, the remote control unit 2602 includes an image information acquisition unit 2701, an information display unit 2702, an instruction acquisition unit 2703, and an extraction order designation unit 2704.

  The image information acquisition unit 2701 acquires the product box image information 1710 together with the location number from the camera control unit 605.

  The information display unit 2702 generates a display screen including the image information in the product box and displays it on the display device 507.

  The instruction acquisition unit 2703 acquires picking instruction data from the overall control unit 600 and notifies the take-out order designation unit 2704 of the picking instruction data. The picking instruction data 2700 in FIG. 27 is an example of picking instruction data that the instruction acquisition unit 2703 acquires from the overall control unit 600.

  As shown in FIG. 27, the picking instruction data 2700 includes “store ID”, “product number”, and “product quantity” as information items. Thereby, in the instruction | indication acquisition part 2703, each robot part 231-234 can specify the goods and the quantity which should be taken out from a goods box. Note that the instruction acquisition unit 2703 also notifies the information display unit 2702 of the product to be taken out from the product box and its quantity. Thereby, the information display unit 2702 can display the product to be taken out from the product box and its quantity on the generated display screen.

  In response to the display screen being displayed by the information display unit 2702, the take-out order designation unit 2704 accepts designation of products to be taken out of the product box and designation of the order in which those products are taken out by the worker 260.

  In addition, the take-out order designating unit 2704 notifies the robot unit of take-out information, which is designated by the worker 260 and should be taken out of the product box and the order in which those products are taken out.

(2) Remote Control Processing by Remote Control Unit Next, the flow of remote control processing by the remote control unit 2602 will be described. FIG. 28 is a first flowchart showing a flow of remote control processing by the remote control unit. Here, the remote control processing when the image information acquisition unit 2701 acquires the image information 1710 in the product box captured by the camera unit 221 and the instruction acquisition unit 2703 acquires the picking instruction data 2700 will be described.

  As illustrated in FIG. 28, in step S2801, the instruction acquisition unit 2703 acquires picking instruction data 2700 from the overall control unit 600.

  In step S2802, the image information acquisition unit 2701 acquires product box image information 1710 photographed by the camera unit 221.

  In step S2803, the information display unit 2702 includes a product to be taken out from the product box (“product number” = “A2”) and its quantity (“product quantity” = “8”), and product box image information 1710. A display screen is displayed on the display device 507.

  In step S2804, the take-out order designating unit 2704 determines whether or not the operator 260 has designated a product to be taken out of the product box and a designation of the order in which those products are to be taken out. If it is determined by operator 260 that no designation has been made (NO in step S2804), the process waits until the designation is completed. On the other hand, if it is determined in step S2804 that the designation is made by the worker 260 (YES in step S2804), the process proceeds to step S2805.

  In step S2805, the take-out order designating unit 2704 notifies the robot unit 231 of take-out information, which is designated by the operator 260, and which is to be taken out of the product box, and the order in which those products are taken out.

  In step S2806, whether or not the remote control unit 2602 has notified extraction information for each product (“product number” = “A2”, “A8”) stored in the “product number” of the picking instruction data 2700. Determine.

  If it is determined in step S2806 that there is a product that has not been notified of take-out information, the process returns to step S2802. On the other hand, if it is determined in step S2806 that the extraction information has been notified for each product (“product number” = “A2”, “A8”) stored in “product number” of the picking instruction data 2700, Ends remote control processing.

(3) Operation Example of Remote Control Unit Next, an operation example of the remote control unit 2602 will be described. Here, an operation example when the image information acquisition unit 2701 acquires the image information in the product box captured by the camera unit 221 and the instruction acquisition unit 2703 acquires the picking instruction data 2700 will be described. FIG. 29 is a first diagram illustrating an operation example of the remote control unit.

  Among these, FIG. 29A shows a state in which the camera unit 221 is moved by the camera movable mechanism unit 622. In the case of FIG. 29A, the camera unit 221 moves to the placement position of “location number” = “1-2”, and photographs the product box of the product of “product number” = “A2”. Thereafter, the camera unit 221 moves to the placement position of “location number” = “1-8”, and takes an image of the product box of the product of “product number” = “A8”.

  FIG. 29B is a diagram illustrating an example of a display screen displayed on the display device 507. Among these, the display screen 2901 indicates that the image information in the product box acquired by the camera unit 221 shooting the product box of the product with “product number” = “A2” is being displayed. .

  According to the display screen 2901, the quantity of the product with “product number” = “A2” to be taken out from the product box is “8”. Therefore, the worker 260 designates eight products to be taken out on the display screen 2901. At this time, the remote control unit 2602 recognizes the order designated by the worker 260 as the extraction order.

  In the display screen 2901 of FIG. 29 (b), a product with a circled number represents a product designated by the worker 260, and the circled number indicates the order in which those products are taken out.

  Similarly, the display screen 2902 indicates that the image information in the product box acquired by the camera unit 221 shooting the product box of the product with “product number” = “A8” is being displayed. .

  According to the display screen 2902, the quantity of the product of “product number” = “A8” to be taken out from the product box is “3”. Therefore, the worker 260 designates three products to be taken out on the display screen 2902. At this time, the remote control unit 2602 recognizes the order designated by the worker 260 as the extraction order.

  In the display screen 2902 of FIG. 29B, the products with circled numbers indicate the products designated by the operator 260, and the circled numbers indicate the order in which those products are taken out.

As is clear from the above description, in the storage system 2600 according to the second embodiment, the remote control unit 2602
-Display the product and quantity to be removed from the product box to the worker.
The image information in the product box is displayed to the worker, and the worker specifies the product to be taken out from the product box and the order in which those products are taken out.

  Thereby, according to the storage system 2600 which concerns on 2nd Embodiment, even if it is a case where replacement to a new product is performed frequently or a product shape diversifies, arrangement | positioning of the product in a product box is carried out It is possible to save the trouble of learning the control device so that it can be recognized. In addition, since the arrangement of the products in the product box is not erroneously recognized, the picking device can reliably take out the products in the product box. That is, according to the storage system 2600 which concerns on 2nd Embodiment, the picking operation | movement according to each goods is realizable.

[Third Embodiment]
In the second embodiment described above, it is assumed that each stage of the conveyor conveys one container at a time, and after the designation of products to be taken out from the product box and the designation of the order of taking out those products are completed, As described above, the image information in the product box is displayed.

  On the other hand, in the third embodiment, on the assumption that each stage of the conveyor conveys two containers at a time, the specification of products to be taken out from the product box and the specification of the order in which those products are taken out are completed. Before the next product box image information is displayed. Hereinafter, the third embodiment will be described focusing on differences from the second embodiment.

<Details of remote control unit>
(1) Functional Configuration of Remote Control Unit FIG. 30 is a second diagram illustrating an example of a functional configuration of the remote control unit. The difference from the remote control unit 2602 shown in FIG. 27 is that the remote control unit 3000 shown in FIG. 30 has a skip instruction unit 3001.

  The skip instruction unit 3001 is an example of a first instruction unit. The skip instruction unit 3001 receives from the worker 260 an instruction to skip (transition) the display screen generated in the information display unit 2702 and displayed on the display device 507 to the next display screen. When the skip instruction unit 3001 receives an instruction to skip to the next display screen, the skip instruction unit 3001 instructs the information display unit 2702 to skip to the next display screen.

  Further, upon receiving an instruction to skip to the next display screen, the skip instruction unit 3001 identifies a product that minimizes the picking time as a product to be picked next, a robot movable mechanism unit 621, a camera movable mechanism Notification to the unit 622. Thereby, the robot movable mechanism unit 621 and the camera movable mechanism unit 622 change the robot movable sequence and the camera movable sequence, respectively.

  In the third embodiment, it is assumed that the image information acquisition unit 2701 acquires the product box image information 3010 illustrated in FIG. 30 as the product box image information captured by the camera unit 221.

(2) Remote Control Processing by Remote Control Unit Next, the flow of remote control processing by the remote control unit 2602 will be described. FIG. 31 is a second flowchart showing a flow of remote control processing by the remote control unit.

  The difference from the flowchart shown in FIG. 28 is step S3101 to step S3102 and step S3103.

  In step S <b> 3101, the take-out order designation unit 2704 accepts designation of products to be taken out from the product box and designation of the order in which those products are taken out.

  In step S <b> 3102, the skip instruction unit 3001 determines whether a skip instruction has been received from the worker 260. If it is determined in step S3102 that a skip instruction has not been accepted (NO in step S3102), the process proceeds to step S2804.

  On the other hand, if it is determined in step S3102 that a skip instruction has been accepted (YES in step S3102), the process proceeds to step S3103.

  When the skip instruction unit 3001 receives the skip instruction, the skip instruction unit 3001 specifies a product (here, “product number” = “A8” product) that minimizes the picking time as a product to be picked next. This is notified to the robot movable mechanism unit 621 and the camera movable mechanism unit 622. As a result, the robot unit 231 and the camera unit 221 move to the placement position of the product box of the product to be picked next (product of “product number” = “A8”).

  In step S3103, the information display unit 2702 specifies the next product box image information (here, product product image information of the product of “product number” = “A8”) that minimizes the picking time, and step S2802 Return to.

(3) Operation Example of Remote Control Unit Next, an operation example of the remote control unit 2602 will be described. FIG. 32 is a second diagram illustrating an operation example of the remote control unit.

  Among these, FIG. 32A shows a state in which the camera unit 221 is moved by the camera movable mechanism unit 622. As shown in FIG. 32A, the camera unit 221 moves to the placement position of “location number” = “1-2”, and photographs the product box of the product of “product number” = “A2”. . Thereafter, the camera unit 221 moves to the placement position of “location number” = “1-8”, and takes an image of the product box of the product of “product number” = “A8”. Further, the camera unit 221 then moves again to the placement position of “location number” = “1-2”, and photographs the product box of the product of “product number” = “A2”.

  FIG. 32B is a diagram illustrating an example of a display screen displayed on the display device 507. Among these, the display screen 3201 is a display screen that is displayed when the camera unit 221 takes a picture of a product box of a product with “product number” = “A2”.

  According to the display screen 3201, the product to be taken out from the product box is the product with “product number” = “A2”, and the quantity of the product to be taken out is “8”. Therefore, the worker 260 designates eight products on the display screen 3201.

  Here, in the case of the display screen 3201, the number of products that can be specified at one time is up to six, and the remaining two products cannot be specified unless picking is completed for the six specified products. .

  On the other hand, it takes a certain amount of time to complete the picking for the six designated products. In such a case, the worker 260 presses the skip button 3210 on the display screen 3201 and inputs a skip instruction.

  When the skip button 3210 is pressed, the information display unit 2702 displays the next product box image information even if the product quantity specified by the worker 260 is less than the quantity to be taken out from the product box. The screen transitions to a screen 3202. According to the display screen 3202, the product to be taken out from the product box is the product with “product number” = “A8”, and the quantity of the product to be taken out is “3”. Therefore, the worker 260 designates three products on the display screen 3202.

  In the information display unit 2702, when the designation of the product and quantity is completed on the display screen 3202, the current product box (that is, after picking is completed) for the product box corresponding to the image information in the product box before skipping. A display screen 3203 including the internal image information is displayed.

  According to the display screen 3203, since picking has been completed for the six products specified previously, the remaining two products can be specified. Therefore, the worker 260 designates the remaining two products on the display screen 3203. This completes the designation of the product and quantity to be taken out for the product box of the product with “product number” = “A2”.

As is clear from the above description, in the storage system 2600 according to the third embodiment, the remote control unit 3000 is
-Display the product and quantity to be taken out of the product box on the display screen.
The image information in the product box is displayed on the display screen, and the operator designates the product to be taken out from the product box and the order of taking out those products.
Even if the specified quantity is less than the quantity to be taken out from the product box, a skip button that can skip to the next product box image information is displayed on the display screen.

  Thus, according to the storage system 2600 according to the third embodiment, when the designation cannot be completed unless picking is performed, the next in-product box image information is displayed by pressing the skip button. be able to.

  As a result, the worker can specify the product to be taken out on the display screen including the next image information in the product box while picking the previously specified product. That is, the picking time can be shortened as compared with the case where the next product box image information cannot be displayed unless the designation is completed.

[Fourth Embodiment]
In the first embodiment, it has been described that the empty box delivery control unit 606 automatically determines whether or not the product box is an empty box based on the image information in the product box. However, when the operator designates a product to be taken out, it is more efficient for the worker to determine the empty box. Therefore, in the fourth embodiment, based on the image information in the product box, it is determined whether or not the worker is an empty box, and the determination result can be manually input. Hereinafter, the fourth embodiment will be described focusing on differences from the third embodiment.

<Functional configuration of storage system>
First, the functional configuration of the storage system according to the fourth embodiment will be described. FIG. 33 is a diagram illustrating an example of a functional configuration of a storage system according to the third embodiment. The difference from the storage system 2600 described with reference to FIG. 26 is that the control device 131 has a remote control unit 3301 in the case of the storage system 3300 shown in FIG.

  The remote control unit 3301 acquires picking instruction data from the overall control unit 600 and identifies the product and quantity to be picked. In addition, the remote control unit 3301 acquires image information in the product box from the camera control unit 605. Further, the remote control unit 3301 displays the image information in the product box on the display device 507 together with the specified product and quantity, and designates the product to be taken out and the order for taking out those products. Accept from 260.

  In addition, the remote control unit 2602 notifies the robot units 231 to 234 of the designation about the products to be taken out and the designation about the order of taking out those products received from the worker 260 as information for taking out.

  Further, the remote control unit 3301 accepts an empty box payout instruction input by the worker 260. When receiving a payout instruction from the worker 260, the remote control unit 3301 notifies the robot unit of the location number of the product box as a payout instruction.

<Details of remote control unit>
Next, details of the remote control unit 3301 of the control device 131 will be described.

(1) Functional Configuration of Remote Control Unit FIG. 34 is a third diagram illustrating an example of a functional configuration of the remote control unit. The difference from the remote control unit 3000 shown in FIG. 30 is that the remote control unit 3301 shown in FIG. 34 has an empty box payout instruction unit 3401.

  The empty box payout instruction unit 3401 is an example of a second instruction unit. The empty box payout instruction unit 3401 receives an empty box payout instruction from the operator 260 on the display screen generated by the information display unit 2702 and displayed on the display device 507. Also, when receiving an empty box payout instruction, the empty box payout instruction unit 3401 notifies the robot unit of the location number of the product box as a payout instruction. Thereby, in the robot part, the said merchandise box can be paid out toward a corresponding conveyor.

  Further, when receiving an empty box payout instruction, the empty box payout instruction unit 3401 notifies the transfer device 133 of the location number of the product box as a transfer instruction. Thereby, in the conveying apparatus 133, a conveyance sequence is changed and the empty box paid out to the conveyor is conveyed to a predetermined position.

  In the fourth embodiment, it is assumed that the image information acquisition unit 2701 acquires the product box image information 3410 illustrated in FIG. 34 as the product box image information captured by the camera unit 221.

(2) Remote Control Processing by Remote Control Unit Next, the flow of remote control processing by the remote control unit 3301 will be described. FIG. 35 is a third flowchart showing the flow of remote control processing by the remote control unit.

  The difference from the flowchart shown in FIG. 31 is steps S3501 and S3502. In step S3501, the empty box payout instruction unit 3401 determines whether an empty box payout instruction has been input. If it is determined in step S3501 that an empty box payout instruction has not been input (NO in step S3501), the process proceeds to step S2804.

  On the other hand, if it is determined in step S3501 that an empty box payout instruction has been input (YES in step S3501), the process proceeds to step S3502. In step S3502, the empty box payout instruction unit 3401 notifies the robot unit 231 of “location number” = “1-2” as a payout instruction.

(3) Operation Example of Remote Control Unit Next, an operation example of the remote control unit 3301 will be described. FIG. 36 is a third diagram illustrating an operation example of the remote control unit.

  Among these, FIG. 36A shows a state in which the camera unit 221 is moved by the camera movable mechanism unit 622. As shown in FIG. 36A, the camera unit 221 moves to the placement position of “location number” = “1-2”, and photographs the product box of the product of “product number” = “A2”. . Thereafter, the camera unit 221 moves to the placement position of “location number” = “1-8”, and takes an image of the product box of the product of “product number” = “A8”. Thereafter, the camera unit 221 moves again to the placement position of “location number” = “1-2”, and takes an image of the product box of the product of “product number” = “A2”.

  FIG. 36B is a diagram illustrating an example of a display screen displayed on the display device 507. Among these, the display screen 3601 indicates that the camera unit 221 is displaying the image information in the product box acquired by photographing the product box of the product with “product number” = “A2”. .

  According to the display screen 3601, the product to be taken out from the product box is the product with “product number” = “A2”, and the quantity of the product to be taken out is “3”. Therefore, the worker 260 designates three products on the display screen 3601.

  Here, in the case of the display screen 3601, the number of products that can be specified at one time is only one, the picking for one specified product is completed, the empty box is paid out, and the next product box Unless the arrangement is completed, the remaining two products cannot be specified.

  In such a case, the worker 260 presses an empty box payout button 3612 on the display screen 3601, and inputs an empty box payout instruction. As a result, the robot unit 231 pays out the product box of the product of “product number” = “A2” after picking up one designated product.

  Note that it takes a certain amount of time to complete the arrangement of the next product box after picking is completed for the designated product and the empty box is paid out. In such a case, the worker 260 inputs a skip instruction by pressing a skip button 3611 on the display screen 3601.

  As a result, the information display unit 2702 displays a display screen 3602 including the next product box image information. According to display screen 3602, the product to be taken out from the product box is the product with “product number” = “A8”, and the quantity of the product to be taken out is “3”. Therefore, the worker 260 designates three products on the display screen 3602.

  In the information display unit 2702, when the designation of the product and quantity is completed on the display screen 3602, the current in-product image information about the product box before skipping (that is, after the picking and empty box payout have been completed). A display screen 3603 including is displayed.

  According to the display screen 3603, the picking, empty box delivery, and arrangement of the next product box for one previously designated product have been completed, so the remaining two products can be designated. Can do. Therefore, the worker 260 designates the remaining two products on the display screen 3603. This completes the designation of the product and quantity to be taken out for the product box of the product with “product number” = “A2”.

As is clear from the above description, in the storage system 3300 according to the fourth embodiment, the remote control unit 3301 is
-Display the product and quantity to be taken out of the product box on the display screen.
The image information in the product box is displayed on the display screen, and the operator designates the product to be taken out from the product box and the order of taking out those products.
-Display on the display screen an empty box payout button for paying out an empty product box as an empty box when the product is taken out.
Even if the specified quantity is less than the quantity to be taken out from the product box, a skip button that can be skipped to the next product box image information is displayed on the display screen.

  Thereby, the operator can pay out empty boxes efficiently.

[Fifth Embodiment]
In the second to fourth embodiments, it has been described that the size of the product (the length in the vertical direction and the length in the width direction) is known when the designation of the product to be taken out from the product box is received from the operator. On the other hand, in the fifth embodiment, when the designation of the product to be taken out from the product box is received from the worker, the designation of the size of the product is received from the worker. Hereinafter, the fifth embodiment will be described focusing on differences from the fourth embodiment.

<Details of remote control unit>
(1) Functional Configuration of Remote Control Unit FIG. 37 is a fourth diagram illustrating an example of a functional configuration of the remote control unit. The difference from the remote control unit 3301 shown in FIG. 34 is that the remote control unit 3700 shown in FIG. 37 has a product size registration unit 3701.

  When the product box photographed by the camera units 221 to 224 is the first type of product box in the lot, the product size registration unit 3701 is displayed on the display screen when the product box image information is acquired. Accept specification of product size.

  In the fifth embodiment, the image information acquisition unit 2701 acquires the product box image information 1710 shown in FIG. 37 as the product box image information of the first product in the product box.

(2) Remote Control Processing by Remote Control Unit Next, the flow of remote control processing by the remote control unit 3700 will be described. FIG. 38 is a fourth flowchart showing the flow of remote control processing by the remote control unit.

  The difference from the flowchart shown in FIG. 35 is steps S3801 and S3802. In step S3801, the product size registration unit 3701 determines whether the product box image information displayed on the display screen by the information display unit 2702 is product box image information of the first product in the product box. To do. If it is determined in step S3801 that the image information is not in the product box of the first product in the product box (NO in step S3801), the process proceeds to step S3101.

  On the other hand, if it is determined in step S3801 that the image information is in the product box of the first product in the product box (YES in step S3801), the process proceeds to step S3802. In step S3802, the product size registration unit 3701 receives an input of the product size from the worker 260.

(3) Operation Example of Remote Control Unit Next, an operation example of the remote control unit 3700 will be described. FIG. 39 is a fourth diagram illustrating an operation example of the remote control unit.

  Among these, FIG. 39A shows a display screen 3901 including image information 1710 in the product box of the first product in the product box, which is photographed by the camera unit 221. On the display screen 3901, the worker 260 inputs the product size by designating the vertex position of the product on the display screen 3901.

  Similarly, FIG. 39B shows a display screen 3902 including image information in the product box of the first product in the product box, which is taken by the camera unit 221. On the display screen 3902, the worker 260 inputs a product size by designating a position corresponding to the vertex position of the circumscribed rectangle of the product on the display screen 3902.

As is clear from the above description, in the storage system 3300 according to the fifth embodiment, the remote control unit 3700
-Display the product and quantity to be taken out of the product box on the display screen.
The image information in the product box is displayed on the display screen, and the operator designates the product to be taken out from the product box and the order of taking out those products.
-Display on the display screen an empty box payout button for paying out an empty product box as an empty box when the product is taken out.
Even if the specified quantity is less than the quantity to be taken out from the product box, a skip button that can skip to the next product box image information is displayed on the display screen.
-When displaying the image information in the product box of the first product in the product box, the operator can input the product size by specifying the position corresponding to the vertex position of the product or the vertex position of the circumscribed rectangle of the product. It has a function.

  Thereby, the worker can input the product size on the display screen.

[Sixth Embodiment]
In the third to fifth embodiments, it is assumed that each stage of the conveyor conveys two containers. Based on the picking instruction data and the replenishment information, picking order information, robot movable order information, camera movable It has been described as generating order information. On the other hand, in the sixth embodiment, it is assumed that each stage of the conveyor conveys two or more containers, and further, picking is performed on the basis of picking instruction data and replenishment information in consideration of the status of each container. Order information, robot movable order information, and camera movable order information are generated. Hereinafter, the sixth embodiment will be described focusing on differences from the above embodiments.

<Details of overall control unit>
(1) Functional Configuration of Overall Control Unit FIG. 40 is a diagram illustrating an example of a functional configuration of the overall control unit. As illustrated in FIG. 40, the overall control unit 600 includes a container data acquisition unit 4001, a priority order determination unit 4002, and a picking instruction data output unit 4003.

  The container data acquisition unit 4001 acquires container data indicating the current state of the container from the picking control unit 604, the remote control unit 2602, or the like.

  The priority order determination unit 4002 determines the priority order between the containers based on the numbering rule for determining the priority order for the container data acquired by the container data acquisition unit 4001.

  Picking instruction data output section 4003 generates and outputs picking instruction data including the priority order determined by priority order determination section 4002.

(2) Operation Example of Overall Control Unit Next, an operation example of the overall control unit 600 will be described with reference to FIGS. 41 and 42. FIG. 41 is a diagram illustrating an operation example of the overall control unit. FIG. 42 is a diagram illustrating another configuration example of the storage system.

  In FIG. 41, container data 4100 is an example of container data acquired by the container data acquisition unit 4001. Note that the container data 4100 shown in FIG. 41 is based on the positions of the products and containers in the storage system 4200 shown in FIG.

  As shown in FIG. 41, the container data 4100 includes “container number”, “picking time”, “transport time”, “total time”, “current location”, and “next location” as information items. included.

  “Container number” stores a number for identifying a container. The “picking time” stores the time taken for picking a product for the container specified by the corresponding “container number”. The time required for picking a product is calculated by multiplying the quantity of the product by a predetermined parameter value.

  “Transport time” is the time taken to transport the container to the position where the next product is picked when the next product is picked from the container specified by the corresponding “container number”. Stored. The conveyance time is calculated by multiplying a predetermined parameter value by the conveyance distance to the position where the next commodity is picked.

  “Total time” stores the total value of the times stored in “picking time” and “transport time”.

  “Current location” stores information indicating the current location of the container specified by the corresponding “container number”. The “next location” stores a location number indicating the next stop position of the container specified by the corresponding “container number”.

  The priority order determination unit 4002 determines the priority order of the container data 4100 based on the priority numbering rule 4110. According to the priority numbering rule 4110 in FIG. 41, the priority determination unit 4002 assigns priorities in ascending order of the sum of the current product picking time and the transport time to the next location. To do. However, in the priority order determination unit 4002, there is no transport time for a container for which a skip instruction is input or a container for which an empty box payout instruction is input, so the priority order after the picking of the current product is completed Is the highest.

  The priority order data 4120 is data indicating the priority order determined based on the priority order numbering rule 4110 for the container data 4100. The priority order data 4120 is output from the picking instruction data output unit 4003 as part of the picking instruction data.

(3) Picking Instruction Data Output Processing by Overall Control Unit Next, the flow of picking instruction data output processing by the overall control unit 600 will be described. FIG. 43 is a flowchart showing the flow of picking instruction data output processing by the overall control unit.

  In step S4301, the overall control unit 600 acquires the container data 4100. In step S4302, overall control unit 600 determines whether or not the picking instruction data that has already been output has been picked.

  If it is determined in step S4302 that picking has not been performed (NO in step S4302), the process waits until it is determined that picking has been performed.

  On the other hand, if it is determined in step S4302 that picking has been executed (YES in step S4302), the process proceeds to step S4303.

  In step S4303, the overall control unit 600 analyzes the container data 4100 according to the priority numbering rule 4110, and calculates the total time for each container.

  In step S4304, the overall control unit 600 determines priorities in ascending order of the calculated total time.

  In step S4305, overall control unit 600 generates and outputs picking instruction data including the determined priority order.

  In step S4306, overall control unit 600 determines whether or not picking has been completed for the containers of all stores included in the lot. If it is determined in step S4306 that there is a container that has not been picked yet (NO in step S4306), the process returns to step S4301. On the other hand, if it is determined in step S4306 that the picking has been completed for all the containers in the lot (if YES in step S4306), the picking instruction data output process is terminated.

As is clear from the above description, in the storage system 3300 according to the sixth embodiment,
The overall control unit
・ Get the current container data.
Based on the acquired container data, a picking time and a transport time are calculated for each container, and the priority order of the containers is determined based on the total time of the picking time and the transport time.
-The determined priority order is included in the picking instruction data and output.

  Thereby, according to the storage system concerning a 6th embodiment, the processing time of the whole lot can be minimized.

[Other Embodiments]
In the first to sixth embodiments, the second transport device has been described as being installed along the end positions on both sides of each of the conveyors 202 to 204 serving as the first transport device. However, you may install a 2nd conveying apparatus along one edge part position of each conveyor 202-204 which is a 1st conveying apparatus.

  In the first to sixth embodiments, the container has been described as being transported from the bottom to the top. However, the transport direction is not limited to this, and the container is transported from the top to the bottom. It may be conveyed. Furthermore, in the first to sixth embodiments, the first transport device and the second transport device are shown as orthogonal to each other, but the first transport device and the second transport device are orthogonal to each other. It does not have to be.

  In the first embodiment, the default value is rewritten using the product height information calculated when the first product in the product box is stored, and the product height information after rewriting is used for the second and subsequent products. It has been described as being used when taking out and storing. However, the calculation timing of the product height information is not limited to the first product in the product box, and may be the Nth product in the product box. In this case, the rewritten product height information is used when the N + 1th and subsequent products are taken out and stored.

  The function of the product height registration unit 1703 described in the first embodiment may be included in the remote control units 2602, 3000, 3301, and 3700 described in the second to sixth embodiments.

  In the sixth embodiment, the priority order is determined so as to minimize the processing time of the entire lot. However, the priority order determination method is not limited to this. For example, the priority order may be determined so that the movable amount of the robot unit is minimized.

  Further, as shown in the sixth embodiment, by sharing the second transfer device between adjacent storage systems, a plurality of storage systems are combined in the horizontal direction to form one storage system. You may make it do.

In addition, in the disclosed technology, forms such as the following supplementary notes are conceivable.
(Appendix 1)
A shelf in which a plurality of product boxes containing different types of products are arranged in a first direction, a mounting shelf formed in a stepped shape in the second direction,
A first transport device installed along each of the plurality of product boxes at each stage and transporting a container in the first direction;
A second transport device installed along an end position of each of the first transport devices, transferring the container to and from each of the first transport devices, and transporting the container in the second direction;
In each stage, the container transported to a predetermined position has a picking device that takes out and stores the product from the corresponding product box,
The picking device takes out products at a position specified by an operator from the product box in an order specified by the operator in an image in the product box taken before taking out the product from the product box. And storage system.
(Appendix 2)
Of the images in each product box that are photographed before taking out the product from the product box and displayed to the worker in the order in which they were photographed, the currently displayed image is transitioned to the next image according to the operator's instructions The storage system according to supplementary note 1, further comprising a first instruction unit.
(Appendix 3)
The first instruction unit includes:
In the image being displayed, even if the quantity of the product at the position specified by the operator is less than a predetermined quantity, the operator gives an instruction to make a transition to the next image. The storage system according to appendix 2, wherein transition to the next image is performed.
(Appendix 4)
In the next image, when a predetermined number of products are specified by the operator, the displayed image is changed to the current image in the product box corresponding to the image before the transition to the next image. The storage system according to appendix 3, wherein the storage system is returned.
(Appendix 5)
The storage system according to appendix 2, wherein images in each product box displayed to the worker are photographed in an order that minimizes processing time.
(Appendix 6)
The order in which the processing time is minimized is the time taken to take out and store the product from the corresponding product box with respect to the container transported to a predetermined position, and the position corresponding to the next product box. The storage system according to appendix 4, wherein the total time with the time taken to transport the container is the minimum order.
(Appendix 7)
The storage system according to claim 2, further comprising a second instruction unit that inputs a payout instruction for paying out the product box corresponding to the image being displayed toward the first transport device. .

  Note that the present invention is not limited to the configurations shown here, such as combinations with other elements, etc., in the configurations described in the above embodiments. These points can be changed without departing from the spirit of the present invention, and can be appropriately determined according to the application form.

100: Warehouse area 130: Storage system 131: Control device 132: Placement shelf 133: Transport device 134: Picking devices 201-204: Conveyor 210: Conveyors 221-224: Camera units 231-234: Robot unit 310: Conveyor 600: Overall control unit 601: Conveyor control unit 602: Robot movement control unit 603: Camera movement control unit 604: Picking control unit 605: Camera control unit 606: Empty box payout control unit 621: Robot movable mechanism unit 622: Camera movable mechanism unit 700 : Replenishment information 801: Instruction acquisition unit 802: Replenishment information reading unit 803: Picking order determination unit 1101: Instruction acquisition unit 1102: Replenishment information reading unit 1103: Robot movable order determination unit 1401: Instruction acquisition unit 1402: Supplementation information reading unit 1403 Camera movable order determination unit 1701: Image information acquisition unit 1702: Arrangement recognition unit 1703: Product height registration unit 1704: Instruction acquisition unit 1705: Extraction order determination unit 1711: Image information acquisition unit 1712: Arrangement recognition unit 1713: Storage position determination Unit 1801: hand 1802: distance sensor 1810: information 1910 indicating extraction order: information 2201 indicating area to be stored 2201: image information acquisition unit 2202: empty box specifying unit 2203: transport control unit 2601: storage control unit 2602: remote control unit 2701: Image information acquisition unit 2702: Information display unit 2703: Instruction acquisition unit 2704: Extraction order designation unit 3000: Remote control unit 3001: Skip instruction unit 3301: Remote control unit 3401: Empty box payout instruction unit 3700: Remote control unit 3701 : Product rhino Registration unit 4001: Container data acquisition unit 4002: priority determining unit 4003: picking instruction data output section

Claims (7)

A shelf in which a plurality of product boxes containing different types of products are arranged in a first direction, a mounting shelf formed in a stepped shape in the second direction,
A first transport device installed along each of the plurality of product boxes at each stage and transporting a container in the first direction;
A second transport device installed along an end position of each of the first transport devices, transferring the container to and from each of the first transport devices, and transporting the container in the second direction;
In each stage, the container transported to a predetermined position has a picking device that takes out and stores the product from the corresponding product box,
The picking device takes out products at a position specified by an operator from the product box in an order specified by the operator in an image in the product box taken before taking out the product from the product box. And storage system.   Of the images in each product box that are photographed before taking out the product from the product box and displayed to the worker in the order in which they were photographed, the currently displayed image is transitioned to the next image according to the operator's instruction. The storage system according to claim 1, further comprising a first instructing unit. The first instruction unit includes:
In the image being displayed, even if the quantity of the product at the position specified by the operator is less than a predetermined quantity, the operator gives an instruction to make a transition to the next image. The storage system according to claim 2, wherein transition is made to the next image.   In the next image, when a predetermined number of products are specified by the operator, the displayed image is changed to the current image in the product box corresponding to the image before the transition to the next image. The storage system according to claim 3, wherein the storage system is returned.   The storage system according to claim 2, wherein images in each product box displayed to the worker are photographed in an order that minimizes processing time.   The order in which the processing time is minimized is the time taken to take out and store the product from the corresponding product box with respect to the container transported to a predetermined position, and the position corresponding to the next product box. 5. The storage system according to claim 4, wherein the order is such that the total time with the time taken to transport the containers is minimized. The storage according to claim 2, further comprising a second instruction unit that inputs a payout instruction for paying out a product box corresponding to the image being displayed toward the first transport device. system.

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