JP6473638B2 - Sorting device, computer program, and sorting method - Google Patents

Description

  The present invention relates to a sorting device that sorts cooked foods for each delivery destination.

  Cooked foods such as lunch boxes, rice balls, and sandwiches manufactured at food factories are sorted for each store as a shipping destination, loaded into a transport container (transport container), and delivered. In order to efficiently sort cooked foods, there has been proposed a sorting apparatus for instructing cooked foods to be introduced for each transport container (Patent Document 1). In the following description, the transport container is referred to as “banju”.

JP-A-5-242122

  However, the conventional sorting apparatus does not consider how to arrange each cooked food within the weight when sorting a plurality of types of cooked food for each weight. When multiple cooked foods are sorted and loaded into the weight without considering the placement in the weight, the lunch box moved within the weight due to truck vibration during delivery and sudden braking to avoid danger Problems such as crushing rice balls occur.

  The present invention has been made in view of such circumstances. The purpose is to provide a sorting device that sorts cooked foods in consideration of the arrangement within the weight.

  The sorting device disclosed in the present specification is a determining unit that determines the number of loaded products and the loading position for each weight in the sorting device that sorts the products based on the dimensions of the products, the number of orders, and the number of weights. And, according to the type of the product, the ranking unit that ranks the products for each number of weights, and the determination unit determined so that the products are arranged in order according to a predetermined direction of the number of weights And a changing unit that changes the loading position of the product.

  According to one aspect of the present invention, it is possible to suppress the occurrence of defects during delivery.

It is a block diagram which shows the structural example of a food system. It is a block diagram which shows the hardware structural example of a sorting apparatus. It is explanatory drawing which shows the example of the record layout of a goods database. It is explanatory drawing which shows the example of the record layout of an order information database. It is a flowchart which shows an example of the procedure of a classification process. It is a flowchart which shows an example of the procedure of a classification process. It is a flowchart which shows an example of the procedure of a loading number calculation process. It is a flowchart which shows an example of the procedure of a loading number calculation process. It is a flowchart which shows an example of the procedure of a loading determination process. It is a flowchart which shows an example of the procedure of a loading determination process. It is a flowchart which shows an example of the procedure of a loading determination process. It is a flowchart which shows an example of the procedure of a loading determination process. It is a flowchart which shows an example of the procedure of a loading determination process. It is a flowchart which shows an example of the procedure of a loading determination process. It is a flowchart which shows an example of the procedure of a loading determination process. It is explanatory drawing which shows an example of the intermediate result of the loading determination process. It is explanatory drawing which shows an example of the margin space of number weight. It is explanatory drawing which shows the example of the weight in the middle of loading goods. It is explanatory drawing which shows an example of the loading layout calculated | required by the loading number calculation process. It is explanatory drawing which shows an example of the record layout of a loading area database. It is a flowchart which shows the procedure of the loading method instruction | indication process. It is explanatory drawing which shows an example of the loading layout after a loading method instruction | indication process. It is explanatory drawing which shows an example of the loading area | region database after a loading method instruction | indication process. It is a flowchart which shows an example of the procedure of a classification process. It is a flowchart which shows an example of the procedure of a classification process.

  Hereinafter, embodiments will be described with reference to the drawings. The sorting apparatus according to the present application is one of the components of the food system. The food system is an information system that manages the manufacture and delivery of cooked foods sold at convenience stores (hereinafter referred to as convenience stores), supermarkets, department stores, and the like. Here, the cooked food (hereinafter referred to as “product”) includes lunch boxes, rice balls, sandwiches, and confectionery such as cream puffs and eclairs. In addition, the weight is a rectangular parallelepiped box including a rectangular bottom plate and a side plate (peripheral wall) extending substantially perpendicularly from the periphery of the bottom plate.

Embodiment 1
FIG. 1 is a block diagram illustrating a configuration example of the food system 1. The food system 1 includes a store POS (point of sale system) device 2, an order management system 3, a food production system 4, a sorting system 5, and a delivery service system 6. The store POS device 2 and the order management system 3 are connected by, for example, a dedicated line. The order management system 3 and the food production system 4 are also connected by, for example, a dedicated line. The food production system 4, the sorting system 5, and the delivery service system 6 are connected by, for example, a LAN (Local Area Network), a WAN (Wide Area Network), the Internet, a telephone line, a satellite line, and the like.

  The store POS device 2 is a computer related to a POS at a convenience store. In FIG. 1, the number of the store POS apparatuses 2 is three, for example. However, there are at least as many store POS devices 2 as there are convenience stores. The store POS device 2 transmits ordering information on products for sale to customers to the order management system 3.

  The order management system 3 is a system for managing order information from the store POS device 2, that is, order information. The order management system 3 transmits the order information received from the store POS device 2 to the food production system 4.

The food manufacturing system 4 is a system that manages manufacturing operations and manufacturing apparatuses for manufacturing products to be delivered to a convenience store. The food manufacturing system 4 receives product order information from the order management system 3.
The sorting system 5 is a system that manages the sorting operation or the sorting device 10 and the transporting device 20 that sorts the products manufactured by the food manufacturing system 4 for each delivery destination store.
The delivery flight system 6 is a system that manages truck flights that deliver products sorted by store. The goods sorted for each store are delivered to the store by truck service in accordance with instructions from the delivery system 6.
The food production system 4, the sorting system 5, and the delivery service system 6 transmit and receive information to each other, and manage products that are delivered to the store in cooperation with each other.

The sorting system 5 includes a sorting device 10 and a transport device 20. The sorting device 10 and the transport device 20 are connected to each other by wire or wireless.
The sorting apparatus 10 is a computer such as a mainframe or a workstation. The sorting device 10 sorts the products for each store, and instructs the transport device 20 how to load the products into the weight.
The conveyance device 20 is a self-running traveling robot having an arm, a picking robot, or the like. The transport device 20 loads the products into the number of each store according to the instruction of the sorting device 10.

FIG. 2 is a block diagram illustrating a hardware configuration example of the sorting apparatus 10. The sorting device 10 includes a CPU (Central Processing Unit) (determining unit, ranking unit, changing unit, first acquiring unit, second acquiring unit , single item determining unit, determining unit ) 11, ROM (Read Only Memory) 12, RAM (Random Access Memory) 13 and hard disk 14. The sorting apparatus 10 includes a disk drive 15, a communication unit 16, a display unit 17, and an operation unit 18. Each component of the sorting apparatus 10 is connected via a bus 10b.

  The CPU 11 controls each component of the sorting device 10. The CPU 11 reads a program (computer program) 10P stored in the hard disk 14 into the RAM 13 and executes the program 10P.

  The ROM 12 is a non-volatile semiconductor memory or a read-only storage medium other than the semiconductor memory. The ROM 12 stores BIOS (Basic Input / Output System) executed by the CPU 11 when the sorting apparatus 10 is activated, firmware, and the like.

  The RAM 13 is a main storage device. The RAM 13 temporarily stores work variables, data, and the like necessary during the process of the CPU 11. The RAM 13 may be replaced with a flash memory, a memory card, or the like.

The hard disk 14 is an auxiliary storage device. The hard disk 14 stores a program 10P executed by the CPU 11. The hard disk 14 may be mounted inside the sorting apparatus 10 or may be placed outside the sorting apparatus 10. Note that the hard disk 14, flash memory capable of storing a large capacity information, CD (Compact Disc), DVD (Digital Versatile Disk), is replaced with an optical disk 10d such BD (Blu-ray (registered trademark) Dis c) May be.

The disk drive 15 is a recording device that reads information from the optical disk 10d, which is an external storage medium, and records the read information on the optical disk 10d.
The communication unit 16 is a modem or a LAN (Local Area Network) card. The communication unit 16 transmits / receives information to / from the order management system 3, each component in the food production system 4, the sorting system 5, and the delivery service system 6. The sorting apparatus 10 is also connected to the Internet via the communication unit 16.

  The display part 17 has screens, such as a liquid crystal display and an organic EL (Electro-Luminescence) display, for example, and displays the various screens concerning the program 10P according to the instruction | indication from CPU11.

  The operation unit 18 is an input device such as a keyboard, a mouse, and a touch panel provided on the screen of the display unit 17 on which the user performs various inputs. The operation unit 18 generates an input signal based on an operation by the user. The generated input signal is output to the CPU 11 via the bus 10b.

  Note that the CPU 11 may read the program 10P from the optical disk 10d via the disk drive 15. The CPU 11 may read the program 10P from an external information processing apparatus or storage device via the communication unit 16. Furthermore, a semiconductor memory 10m such as a flash memory storing the program 10P may be mounted in the sorting apparatus 10.

Next, a database used by the sorting apparatus 10 will be described. FIG. 3 is an explanatory diagram showing an example of the record layout of the product database 141. The product database 141 is stored in, for example, the hard disk 14. The product database 141 includes a product code column, a product name column, a category column, a column, a row, a height column, a gap column, a weight column, a shape column, a stackability column, and a column number column. The product code string stores a code (identification information) that uniquely specifies a product. The product name column stores the product name. The category column stores symbols, numbers, etc. indicating the category (type) of the product. For example, let A be a category of products that are in a container such as a lunch box and are not easily crushed. Let B be the category of products that are not in containers such as rice balls but are difficult to deform. Let C be the category of products that are not in a container, such as cream puffs, and that are easily crushed. The column stores the vertical dimension value of the product. The row stores the horizontal dimension value of the product. The height column stores the dimension value of the product height. The gap row stores the dimension value of the gap to be provided between the product and the next product or the wall of the watch weight when the product is loaded on the watch. The weight column stores the weight of the product. The shape column stores symbols, numbers, and the like indicating the shape of the product. For example, 1 if the product is in a round container, 2 if the product is in a rectangular container, 3 if the product is a round rice ball, 4 if the product is a triangular rice ball, 5 if the product is a round candy, 6 if it is a long and thin candy. The stackability column stores the value of a stackability flag that indicates whether or not products can be stacked when they are stacked in order. A value of 1 indicates that stacking is possible. A value of 0 indicates that stacking is not possible. When the stacking is possible, the column of number of stages stores the number of stages that can be stacked (allowable number of stages).

FIG. 4 is an explanatory diagram showing an example of the record layout of the order information database 142. The order information database 142 is stored in the hard disk 14, for example. The order information database 142 includes a store code column, a product code column, and an order quantity column. The store code string stores the code of the store associated with the order information, that is, the store that placed the order. The product code string stores the code of the ordered product. The order quantity column stores the quantity ordered (order quantity) .

  Although the product database 141 and the order information database 142 are stored in the hard disk 14, the present invention is not limited thereto. It may be stored in the order management system 3 or the food production system 4 other than the sorting device 10, or may be stored in a database device accessible from other sorting devices 10.

  Next, information processing performed by the sorting apparatus 10 will be described. 5 and 6 are flowcharts showing an example of the procedure of the sorting process. The CPU 11 of the sorting apparatus 10 reads the order information from the order information database 142 (step S1). The CPU 11 divides the read order information into store codes and selects a store to be processed (step S2). The CPU 11 sets the size of the load for loading the product as a variable. The CPU 11 sets the value of the vertical dimension of the weight in the variable G, the value of the horizontal dimension of the weight in the variable H, and the value of the height dimension of the weight in the variable I (step S3). Each of the dimensions is an internal dimension of a weight that defines a storage space for the product. The CPU 11 selects one of the products manufactured by the food manufacturing system 4 and waiting for sorting for each store (step S4). The CPU 11 reads information on the selected product (step S5). The CPU 11 determines whether or not the selected product is a product ordered from the processing target store (step S6). If the CPU 11 determines that the selected product is not an ordered product (NO in step S6), the process returns to step S4. When the CPU 11 determines that the selected product is an ordered product (YES in step S6), the CPU 11 sets the size of the product as a variable. The CPU 11 sets the value of the vertical dimension of the product in the variable C, the value of the horizontal dimension of the product in the variable D, the value of the height dimension of the product in the variable E, and the value of the gap dimension of the product in the variable F. (Step S7).

  CPU11 calculates the number (loading number) which loads the selected goods (step S8). This loading number calculation process will be described later. The CPU 11 determines whether there is a remaining number (step S9). That is, it is determined whether or not it is possible to load products for the number of orders. If the CPU 11 determines that there is a remaining number (YES in step S9), it sets a new weight and sets the size of the weight to each variable (step S10). This process is the same process as step S3 described above. The CPU 11 returns the process to step S8.

  When determining that there is no remaining number (NO in step S9), the CPU 11 determines whether there is another unprocessed product (step S11). If the CPU 11 determines that there is another product (YES in step S11), the CPU 11 determines whether there is a margin in the number (step S12). If the CPU 11 determines that there is room in the weight (YES in step S12), the process returns to step S4. If the CPU 11 determines that there is no allowance for the weight (NO in step S12), it sets a new weight and sets the size of the weight to each variable (step S13). This process is the same as the above-described step S3 and step S10. The CPU 11 returns the process to step S4.

  If the CPU 11 determines that there is no other product (NO in step S11), the CPU 11 instructs the transfer device 20 on the loading method (step S14). The CPU 11 determines whether there is an unprocessed store or a store that has not been processed (step S15). If the CPU 11 determines that there is an unprocessed store or a store that has not been processed (YES in step S15), the process returns to step S2. If the CPU 11 determines that there are no unprocessed stores and stores that have not been processed (NO in step S15), the sorting process is terminated.

In addition, when CPU11 performs step S4, when manufacture of no goods matched with the process target store is not completed, CPU11 returns a process to step S2 and performs the process about another store. Also good.
If some products associated with the store to be processed have been sorted, but the remaining products have not been manufactured and cannot be loaded, the processing for that store is interrupted, You may perform the process of the other store which has not completed the sorting process.

Next, the loading number calculation process will be described. 7 and 8 are flowcharts showing an example of the procedure of the loading number calculation process. The CPU 11 performs a loading determination process (step S21). 9 to 15 are flowcharts showing an example of the procedure of the loading determination process. The CPU 11 calculates how many items can be loaded in the horizontal direction when the horizontal direction of the product is matched with the horizontal direction of the weight. The horizontal dimension of the weight is H, the horizontal dimension of the product is D, and a gap of a dimension F ( a gap of a predetermined dimension) is provided between adjacent products, so the CPU 11 obtains Nc1 by the equation (1) (step S41).

  Nc1 = H div (D + F) (1)

  Here, the operator div is an operator for obtaining the integer part of the divided quotient. A div B = C indicates that the value of the quotient when A is divided by B is C.

  The CPU 11 determines whether Nc1 is greater than 0 (step S42). If the CPU 11 determines that Nc1 is greater than 0 (YES in step S42), the CPU 11 determines whether equation (2) is satisfied (step S43).

  H mod (D + F) ≧ F (2)

  Here, the operator mod is an operator for obtaining a remainder of division. A mod B = D indicates that the remainder of dividing A by B is D.

  In Formula (1), the clearance between the product at one end in the parallel direction of the plurality of products and the side plate of the weight is considered, but the clearance between the product at the other end and the side wall of the weight is not taken into consideration. ) To determine whether the other gap can be provided.

CPU11 is, (YES in step S 43) If the equation (2) holds, i.e. if it can secure a gap, the process proceeds to step S45. If the expression (2) does not hold (NO in step S43), that is, if the gap cannot be secured, the CPU 11 reduces the number Nc1 loaded in the horizontal direction (step S44).

  Similarly, the CPU 11 calculates how many items can be loaded in the vertical direction when the horizontal direction of the product is matched with the horizontal direction of the weight. The vertical dimension of the weight is G, the vertical dimension of the product is C, and a gap of size F is provided between the adjacent products, so the CPU 11 obtains Nr1 by Expression (3) (step S45).

  Nr1 = G div (C + F) (3)

  The CPU 11 determines whether Nr1 is greater than 0 (step S46). If the CPU 11 determines that Nr1 is greater than 0 (YES in step S46), the CPU 11 determines whether equation (4) is satisfied (step S47).

  G mod (C + F) ≧ F (4)

  In Formula (3), the clearance between the product at one end in the parallel direction of the plurality of products and the side plate of the weight is considered, but the clearance between the product at the other end and the side wall of the weight is not taken into consideration. ) To determine whether the other gap can be provided.

  CPU11 advances a process to step S49, when Formula (4) is materialized (it is YES at step S47), ie, when a clearance gap is securable. When the expression (4) is established (NO in step S47), that is, when the gap cannot be secured, the CPU 11 reduces the number Nr1 loaded in the vertical direction (step S48).

The CPU 11 multiplies the number Nc1 that can be loaded in the horizontal direction by the number Nr1 that can be loaded in the vertical direction to calculate the number N1 of products that can be loaded (step S49). When the CPU 11 determines that Nc1 is 0 or less (NO in step S42), or Nr1 is determined to be 0 or less (NO in step S46), the CPU 11 sets the number N1 that can be loaded to 0 (step S50), and performs the processing step. Move to S70. FIG. 16 is an explanatory diagram showing an example of the intermediate result of the loading determination process. FIG. 16 shows a plan view of the number of goods loaded with goods. In the example shown in FIG. 16, the case where goods are loaded in the right direction and the left direction from the lower left is shown. There is a marginal space (empty space) in the upper part and the right part of FIG. Next, the CPU 11 tries to load the spare space with the direction of the product changed.

  The CPU 11 calculates the vertical dimension G 'and the horizontal dimension H' of the margin space (step S51). FIG. 17 is an explanatory view showing an example of a margin space for numbering. FIG. 17 is a plan view similar to FIG. The upper right part of FIG. 17 is a part where two margin spaces overlap. Therefore, when considering the loading of products into the marginal space, consider when overlapping portions are included in the vertical marginal space as shown in FIG. 17A and when overlapping portions are included in the horizontal marginal space as shown in FIG. 17B. There is a need. The former process will be described.

  The CPU 11 calculates the number Nc11 of products that can be loaded in the horizontal direction and the number Nr11 of products that can be loaded in the vertical direction in the marginal space where the vertical dimension is G 'and the horizontal dimension is H-H' (step S52). The CPU 11 determines whether Nc11 = 0 or Nr11 = 0 (step S53). If the CPU 11 determines that Nc11 = 0 or Nr11 = 0 (YES in step S53), the process proceeds to step S56. When determining that Nc11 and Nr11 are not 0 (NO in step S53), the CPU 11 determines whether or not a gap can be secured at the end in the horizontal direction (step S54). If the CPU 11 determines that a gap can be secured (YES in step S54), the process proceeds to step S56. If the CPU 11 determines that a gap cannot be secured (NO in step S54), the number Nc11 is decreased (step S55).

  The CPU 11 calculates the number Nc12 of products that can be loaded in the horizontal direction and the number Nr12 of products that can be loaded in the vertical direction in the marginal space where the vertical dimension is G and the horizontal dimension is H '(step S56). The CPU 11 determines whether Nc12 = 0 or Nr12 = 0 (step S57). If the CPU 11 determines that Nc12 = 0 or Nr12 = 0 (YES in step S57), the process proceeds to step S60. If the CPU 11 determines that Nc12 and Nr12 are not 0 (NO in step S57), the CPU 11 determines whether a gap can be secured at the end in the vertical direction (step S58). If the CPU 11 determines that a gap can be secured (YES in step S58), the process proceeds to step S60. If the CPU 11 determines that the gap cannot be secured (NO in step S58), the number Nr12 is decreased (step S59). The CPU 11 calculates the number N1 'of products that can be loaded in the two extra spaces (step S60).

  Next, the CPU 11 performs processing when the overlapping portion is included in the horizontally long space as shown in FIG. 17B. The CPU 11 calculates the number Nc13 of products that can be loaded in the horizontal direction and the number Nr13 of products that can be loaded in the vertical direction in the marginal space where the vertical dimension is G 'and the horizontal dimension is H (step S61). The CPU 11 determines whether Nc13 = 0 or Nr13 = 0 (step S62). If the CPU 11 determines that Nc13 = 0 or Nr13 = 0 (YES in step S62), the process proceeds to step S65. When determining that Nc13 and Nr13 are not 0 (NO in step S62), the CPU 11 determines whether or not a gap can be secured at the lateral end (step S63). If the CPU 11 determines that a gap can be secured (YES in step S63), the process proceeds to step S65. If the CPU 11 determines that the gap cannot be secured (NO in step S63), the number Nc13 is decreased (step S64).

  The CPU 11 calculates the number Nc14 of products that can be loaded in the horizontal direction and the number Nr14 of products that can be loaded in the vertical direction in the marginal space where the vertical dimension is G-G 'and the horizontal dimension is H' (step S65). The CPU 11 determines whether Nc14 = 0 or Nr14 = 0 (step S66). If the CPU 11 determines that Nc14 = 0 or Nr14 = 0 (YES in step S66), the process proceeds to step S69. If the CPU 11 determines that Nc14 and Nr14 are not 0 (NO in step S66), the CPU 11 determines whether a gap can be secured at the end in the vertical direction (step S67). If the CPU 11 determines that a gap can be secured (YES in step S67), the process proceeds to step S69. If the CPU 11 determines that a gap cannot be secured (NO in step S67), the number Nr14 is decreased (step S68). The CPU 11 calculates the number N1 ″ of products that can be loaded in the two spare spaces (step S69).

  Subsequently, the CPU 11 calculates how many items can be loaded in the horizontal direction when the vertical direction of the product is aligned with the horizontal direction of the weight. The horizontal dimension of the weight is H, the vertical dimension of the product is C, and a gap of size F is provided between the adjacent products, so the CPU 11 obtains Nc2 from Equation (5) (step S70).

  Nc2 = H div (C + F) (5)

  The CPU 11 determines whether Nc2 is greater than 0 (step S71). If the CPU 11 determines that Nc2 is greater than 0 (YES in step S71), the CPU 11 determines whether equation (6) is satisfied (step S72).

  H mod (C + F) ≧ F (6)

  In Formula (5), the clearance between the product at one end in the parallel direction of the plurality of products and the side plate of the weight is considered, but the clearance between the product at the other end and the side wall of the weight is not considered. ) To determine whether the other gap can be provided.

  CPU11 advances a process to step S74, when Formula (6) is materialized (it is YES at step S72), ie, when a clearance gap is securable. When the expression (6) is established (NO in step S72), that is, when the gap cannot be secured, the CPU 11 reduces the number Nc2 loaded in the horizontal direction (step S73).

  Similarly, the CPU 11 calculates how many items can be loaded in the vertical direction when the vertical direction of the product is aligned with the horizontal direction of the weight. The vertical dimension of the weight is G, the horizontal dimension of the product is D, and a gap of size F is provided between the adjacent products, so the CPU 11 obtains Nr2 from Equation (7) (step S74).

  Nr2 = G div (D + F) (7)

  The CPU 11 determines whether Nr2 is greater than 0 (step S75). If the CPU 11 determines that Nr2 is greater than 0 (YES in step S75), the CPU 11 determines whether or not equation (8) is satisfied (step S76).

  H mod (D + F) ≧ F (8)

  In Formula (7), the clearance between the product at one end in the parallel direction of the multiple products and the side plate of the weight is considered, but the clearance between the product at the other end and the side wall of the weight is not considered. ) To determine whether the other gap can be provided.

  CPU11 advances a process to step S78, when Formula (8) is materialized (it is YES at step S76), ie, when a clearance gap is securable. When the equation (8) is established (NO in step S76), that is, when the gap cannot be secured, the CPU 11 reduces the number Nr2 loaded in the vertical direction (step S77).

  The CPU 11 multiplies the number Nc2 that can be loaded in the horizontal direction by the number Nr2 that can be loaded in the vertical direction, and calculates the number N2 that can be loaded by the product (step S78). When the CPU 11 determines that Nc2 is 0 or less (NO in step S71) or Nr2 is determined to be 0 or less (NO in step S75), the CPU 11 sets the number N2 that can be loaded to 0 (step S80), and performs the process step. Move to S99.

  Next, as in FIG. 16, when products are loaded from the lower left to the right and left, marginal spaces remain in the upper and right portions as in FIG. The CPU 11 tries to load the spare space with the product direction changed.

  The CPU 11 calculates the vertical dimension G ″ and the horizontal dimension H ″ of the margin space (step S79). Similar to the above, when considering loading products into the marginal space, when overlapping portions are included in the vertical marginal space as shown in FIG. 17A and when overlapping portions are included in the horizontal marginal space as shown in FIG. 17B We will divide and consider. The former process will be described.

  The CPU 11 calculates the number Nc21 of products that can be loaded in the horizontal direction and the number Nr21 of products that can be loaded in the vertical direction in the marginal space where the vertical dimension is G ″ and the horizontal dimension is H−H ″ (step S81). The CPU 11 determines whether Nc21 = 0 or Nr21 = 0 (step S82). If the CPU 11 determines that Nc21 = 0 or Nr21 = 0 (YES in step S82), the process proceeds to step S85. When the CPU 11 determines that Nc21 and Nr21 are not 0 (NO in step S82), the CPU 11 determines whether or not a gap can be secured at the lateral end (step S83). If the CPU 11 determines that a gap can be secured (YES in step S83), the process proceeds to step S85. If the CPU 11 determines that the gap cannot be secured (NO in step S83), the number Nc21 is decreased (step S84).

  The CPU 11 calculates the number Nc22 of products that can be loaded in the horizontal direction and the number Nr22 of products that can be loaded in the vertical direction in the marginal space where the vertical dimension is G and the horizontal dimension is H ″ (step S85). The CPU 11 determines whether Nc22 = 0 or Nr22 = 0 (step S86). If the CPU 11 determines that Nc22 = 0 or Nr22 = 0 (YES in step S86), the process proceeds to step S89. If the CPU 11 determines that Nc22 and Nr22 are not 0 (NO in step S86), the CPU 11 determines whether a gap can be secured at the end in the vertical direction (step S87). If the CPU 11 determines that a gap can be secured (YES in step S87), the process proceeds to step S89. If the CPU 11 determines that a gap cannot be secured (NO in step S87), the number Nr22 is reduced (step S88). The CPU 11 calculates the number N2 'of products that can be loaded in the two extra spaces (step S89).

  Next, the CPU 11 performs processing when the overlapping portion is included in the horizontally long space as in FIG. 17B. The CPU 11 calculates the number Nc23 of products that can be loaded in the horizontal direction and the number Nr23 of products that can be loaded in the vertical direction in the marginal space where the vertical dimension is G ″ and the horizontal dimension is H (step S90). The CPU 11 determines whether Nc23 = 0 or Nr23 = 0 (step S91). If the CPU 11 determines that Nc23 = 0 or Nr23 = 0 (YES in step S91), the process proceeds to step S94. When the CPU 11 determines that Nc23 and Nr23 are not 0 (NO in step S91), the CPU 11 determines whether or not a gap can be secured at the lateral end (step S92). If the CPU 11 determines that a gap can be secured (YES in step S92), the process proceeds to step S94. If the CPU 11 determines that the gap cannot be secured (NO in step S92), the number Nc23 is decreased (step S93).

  The CPU 11 calculates the number Nc24 of products that can be loaded in the horizontal direction and the number Nr24 of products that can be loaded in the vertical direction in the marginal space where the vertical dimension is G-G "and the horizontal dimension is H" (step S94). The CPU 11 determines whether Nc24 = 0 or Nr24 = 0 (step S95). If the CPU 11 determines that Nc24 = 0 or Nr24 = 0 (YES in step S95), the process proceeds to step S98. When the CPU 11 determines that Nc24 and Nr24 are not 0 (NO in step S95), the CPU 11 determines whether or not a gap can be secured at the longitudinal end (step S96). If the CPU 11 determines that a gap can be secured (YES in step S96), the process proceeds to step S98. If the CPU 11 determines that the gap cannot be secured (NO in step S96), the number Nr24 is reduced (step S97). The CPU 11 calculates the number N2 ″ of products that can be loaded in the two spare spaces (step S98).

  The CPU 11 determines whether or not the number N1 of products that can be loaded when the horizontal direction of the products is aligned with the horizontal direction of the weight is 0 (step S99). If the CPU 11 determines that the number N1 is 0 (YES in step S99), the process proceeds to step S103. When the CPU 11 determines that the number N1 is not 0 (NO in step S99), the CPU 11 determines in which pattern the number increases with respect to the number of products that can be loaded in the spare space studied in the two patterns (step S100). . When the CPU 11 determines that the number N1 ′ in the first studied pattern is larger than the number N1 ″ in the second examined pattern (YES in step S100), the CPU 11 determines that the number N1 ′ into which the product can be loaded is N1 ′. And flag1 is set to 1 (step S101). When the CPU 11 determines that the number N1 ″ in the second studied pattern is greater than or equal to the number N1 ′ in the first studied pattern (NO in step S100), the CPU 11 determines that the number N1 into which the product can be loaded is N1. '' Is added and flag1 is set to 2 (step S102).

  The CPU 11 determines whether or not the number N2 of products that can be loaded when the vertical direction of the products is aligned with the horizontal direction of the weight is 0 (step S103). If the CPU 11 determines that the number N2 is 0 (YES in step S103), the process proceeds to step S107. When the CPU 11 determines that the number N2 is not 0 (NO in step S103), the CPU 11 determines in which pattern the number increases with respect to the number of products that can be loaded in the spare space examined in the two patterns (step S104). . When the CPU 11 determines that the number N2 ′ in the first studied pattern is larger than the number N2 ″ in the second studied pattern (YES in step S104), the CPU 11 determines that the number N2 ′ into which the product can be loaded is N2 ′. And flag2 is set to 1 (step S105). When the CPU 11 determines that the number N2 ″ in the second studied pattern is greater than or equal to the number N2 ′ in the first studied pattern (NO in step S104), the CPU 11 determines that the number N2 into which the product can be loaded is N2 '' Is added and flag2 is set to 2 (step S106).

  The CPU 11 determines whether or not the numbers N1 and N2 into which products can be loaded are 0 (step S107). If the CPU 11 determines that the number N1 or N2 is not 0 (NO in step S107), it determines whether N1 is greater than N2 (step S108). If the CPU 11 determines that N1 is greater than N2 (YES in step S108), the CPU 11 sets N1 as the maximum number N of products to be stacked and sets flag to 1 (step S109). If the CPU 11 determines that N1 is N2 or less (NO in step S108), the CPU 11 sets N2 as the maximum number N of products that can be loaded, and sets flag to 2 (step S110).

  The CPU 11 stores, in a temporary area provided in the RAM 13 or the hard disk 14, layout information indicating how products are loaded in order of importance based on the value of flag and the values of flag 1 and flag 2. At the same time, the vertical dimension value and the horizontal dimension value of the spare space where the product is not loaded are updated to the variable G indicating the vertical dimension of the weight and the variable H indicating the horizontal dimension (step S111). The CPU 11 ends the loading determination process and returns the process to the caller. Thereby, the CPU 11 treats the extra space as a pseudo weight, and determines whether or not other products can be loaded in the subsequent processing.

  FIG. 18 is an explanatory diagram showing an example of the number of goods in the middle of loading a product. FIG. 18 is a plan view of the weight. A product P1 is stacked in a rectangular area having a vertical dimension G-G 'and a horizontal dimension H-H', and a product P2 is stacked in a rectangular area having a vertical dimension G and a horizontal dimension H '. A rectangular area having a vertical dimension G ′ and a horizontal dimension H-H ′ is a marginal space in which products are not yet loaded.

  When the CPU 11 determines that the numbers N1 and N2 are 0 (YES in step S107), the CPU 11 sets the number N of products to be loaded to 0 (step S112), and returns the process to the caller.

  The processing moves to step S22 in FIG. As a result of the loading determination process, the CPU 11 determines whether or not a product can be loaded (step S22). The CPU 11 determines whether or not the number N of products that can be loaded is zero. If the CPU 11 determines that loading is not possible, that is, the number N is 0 (NO in step S22), the loading number calculation process ends, and the process returns to the caller.

  When the CPU 11 determines that loading is possible, that is, the number N is 1 or more (YES in step S22), the CPU 11 determines whether the selected product can be stacked (step S23). This determination is made based on the stackability flag included in the product information. If the CPU 11 determines that stacking is possible, that is, the stackability flag is 1 (YES in step S23), the CPU 11 sets the number of stages to 2 (step S24). Further, the CPU 11 subtracts the height dimension E of the product from the variable I indicating the height dimension of the weight. Furthermore, the CPU 11 subtracts the number that can be loaded from the remaining number of products. The CPU 11 determines whether or not the number of stages is equal to or less than the allowable number of stages for stacking (step S25). This determination uses the value of the number of stages included in the product information. When the CPU 11 determines that the number of steps is equal to or less than the allowable number of steps (YES in step S25), the CPU 11 determines whether there is a margin for further stacking products. That is, the CPU 11 determines whether or not the value of IE is 0 or more (step S26). When determining that the value of IE is 0 or more (YES in step S26), the CPU 11 determines whether or not the remaining number is larger than the number that can be loaded. (Step S27). When the remaining number is larger than the loadable number (YES in step S27), the CPU 11 subtracts the loadable number from the remaining number (step S28). The CPU 11 subtracts E from the value of I and increases the number of stages by 1 (step S29). CPU11 returns a process to step S25.

  If the CPU 11 determines that the number of steps exceeds the allowable number of steps (NO in step S25), or if the CPU 11 determines that there is not enough room to stack one more product (NO in step S26), the number of steps is set to 1. Decrease (step S32) and return the processing to the caller.

  If the remaining number is less than or equal to the loadable number (NO in step S27), the CPU 11 sets the remaining number to 0 (step S30). The CPU 11 subtracts E from I (step S31). The CPU 11 reduces the number of stages by 1 (step S32), and returns the process to the caller.

  If the CPU 11 determines that stacking is not possible, that is, the stacking permission / inhibition flag is 0 (NO in step S23), the CPU 11 determines whether or not the remaining number is larger than the loadable number (step S33). If the remaining number is larger than the loadable number (YES in step S33), the CPU 11 subtracts the loadable number from the remaining number (step S34) and returns the process to the caller. If the remaining number is less than or equal to the loadable number (NO in step S33), the CPU 11 sets the remaining number to 0 (step S35) and returns the process to the caller.

  Next, the loading method instruction process will be described. FIG. 19 is an explanatory diagram showing an example of the loading layout obtained by the loading number calculation process. FIG. 19 is a plan view of the weight. The vertical direction is the Y axis with the corner of the bottom left of the page as the origin, and the horizontal direction intersecting it is the X axis. The example shown in FIG. 19 shows a layout in which cream puffs, hamburger lunches, rice balls / plums, Makunouchi lunch boxes, rice balls / rice cakes are loaded. The area in which each product is loaded is a rectangle, and is defined by the coordinate value of the lower left point and the coordinate value of the upper right point. Further, it is assumed that the number is loaded with the left side of the paper facing the front side of the truck.

FIG. 20 is an explanatory diagram showing an example of the record layout of the loading area database 143. The loading area database 143 includes a store code column, a flight name column, a watch number column, a product code column, a product name column, a number column, a coordinate 1 column, and a coordinate 2 column. The store code string stores a store code corresponding to the loading area. In the flight name column, the flight name of the delivery flight corresponding to the loading area is stored. The watch number No column stores the continuation number of the number assigned to each store and each flight number. The product code string stores a code corresponding to the product. The product name column stores the name of the product to be loaded. The number column stores the number of products to be loaded in the loading area (number of loaded items) . The coordinate 1 column stores the coordinate value of the lower left coordinate that defines the loading area. The coordinate 2 column stores the coordinate value of the upper right coordinate that defines the loading area.

FIG. 21 is a flowchart showing the procedure of the loading method instruction process. The CPU 11 of the sorting apparatus 10 selects one number among the numbers corresponding to the stores and flights to be processed (step S121). The CPU 11 reads the loading area data corresponding to the selected number from the loading area database 143 (step S122). The CPU 11 performs grouping with reference to the Y coordinate of the point that defines each loading area that has been read (step S123). The Y coordinate is divided by the deceleration of the truck, and the products loaded in the stack move in the -X-axis direction (forward direction) and press the adjacent products in the front-rear direction, but are adjacent in the Y-axis direction. This is because the product is hardly affected. Here, the X-axis direction, that is, the front-rear direction corresponds to the predetermined direction.

  The CPU 11 selects one group (step S124). The CPU 11 sorts the loading areas in the selected group by the X coordinate (step S125). The CPU 11 performs subgrouping based on the sorting result and the X coordinate of each loading area (step S126).

The CPU 11 performs sorting according to the product category associated with each loading area in the group (step S127). In the sorting, the sorting is performed in the order from the one that is not easily crushed to the one that is easily crushed. In the first embodiment, sorting is performed in the order of categories A, B, and C. Here, the order from the one that is not easily crushed to the one that is easily crushed corresponds to the order of rank.

  In the sub group, if there is a product that is more likely to be crushed than the products to be compared among the products included in the sub group, the sub group is the front and the product to be compared is the back. In addition, if there is a product that is less likely to be crushed than the product to be compared among the products included in the subgroup, the product to be compared is placed in front and the subgroup is placed in the back.

  The CPU 11 updates the coordinates stored in the loading area database 143 based on the sorting result (step S128). The CPU 11 determines whether there is an unprocessed group (step S129). If the CPU 11 determines that there is an unprocessed group (YES in step S129), the process returns to step S124. If the CPU 11 determines that there is no unprocessed group (NO in step S129), the CPU 11 determines whether there is an unprocessed number (step S130). If the CPU 11 determines that there is an unprocessed weight (YES in step S130), the process returns to step S121. If the CPU 11 determines that there is no unprocessed weight (NO in step S130), it outputs a loading method (step S131) and returns the process to the caller. The output of the loading method is, for example, transmitting the contents of the loading area database 143 to the transport device 20. When a product is loaded not by the conveyance device 20 but by a person, the placement within the number may be displayed on the screen based on the loading area database 143.

  Next, the contents of the loading method instruction processing will be described by taking the layout shown in FIG. 19 as an example. FIG. 22 is an explanatory diagram showing an example of the loading layout after the loading method instruction processing. FIG. 23 is an explanatory diagram showing an example of the loading area database 143 after the loading method instruction processing.

  The CPU 11 selects the number No. 1 (Step S121). The CPU 11 reads the loading area data of the selected number from the loading area database 143 (step S122). The five records shown in FIG. 20 are read. The CPU 11 performs grouping based on the Y coordinate (step S123). The layout shown in FIG. 19 is divided into two groups. One group (denoted as group 1) is composed of a cream cream loading area A11 (denoted as area A11) and a hamburger lunch loading area A12 (denoted as area 12). The other group (referred to as group 2) is a rice ball / plum loading area A21 (referred to as area A21), a rice ball / rice picking area A22 (referred to as area A22), and a curtain lunch box loading area A23 (referred to as area A23). ).

  The CPU 11 selects group 1 (step S124). The CPU 11 sorts the loading area of group 1 by the X coordinate (step S125). The order is the area A11 and the area A12. The CPU 11 performs subgrouping (step S126), but the subgroup and group 1 are the same. The CPU 11 sorts the areas A11 and A12 by category (step S127). Since the area A11 corresponds to the cream puff, the category is C. Since the area A12 corresponds to the hamburger lunch, it is a category A. Therefore, the areas A12 and A11 are arranged in this order by sorting. The CPU 11 updates the coordinates (step S128).

  Since group 2 is unprocessed, the CPU 11 determines YES in step S129, and selects group 2 in step S124. The CPU 11 sorts the area of group 2 by the X coordinate (step S125). As a result, rice ball / plum loading area A21 (denoted as area A21), curtain inner lunch box loading area A23 (denoted as area A23), and rice ball / salmon loading area A22 (denoted as area A22) are arranged in this order. The CPU 11 divides the area A21 into one subgroup and the areas A22 and A23 into another subgroup (step S126).

  The CPU 11 sorts by category (step S127). The region A21 corresponds to rice balls and plums, the category is B, the region A22 corresponds to rice balls and rice cakes, the category is B, and the region A23 corresponds to the inner lunch box of the curtain, and the category is A. Since both the area A21 and the area A22 have the category B, the replacement is not necessary. However, since the area A23 is the category A, the replacement with the A21 is necessary. Since the area A22 belongs to the same subgroup as the area A23, the area A22 is also a replacement target. As a result of the sorting, the order is area A22, area A23, and area A21. The CPU 11 updates the loading area database 143 according to the sorting result (step S128). Since there is no unprocessed group, the CPU 11 determines NO in step S129, and performs the processes in and after step S130.

  By the loading method instruction processing, the layout shown in FIG. 19 becomes the layout shown in FIG. The positions of the cream cream loading area A11 and the hamburger lunch loading area A12 are interchanged. In addition, the rice ball / plum loading area A21, the rice ball / rice cake loading area A22, and the inner lunch box loading area A23 are switched in position. Then, the loading area database 143 shown in FIG. 20 is also updated and updated to the coordinates shown in FIG.

  The sorting apparatus 10 according to the first embodiment has the following effects. In the car weight, the conveyance device 20 is instructed to load a product that is not easily crushed at a position on the front side of the truck and a product that is easily crushed at a position on the rear side of the truck. As a result, it is possible to suppress the occurrence of a problem that the product is crushed even when the product moves within the load due to the deceleration caused by the sudden braking to avoid danger during delivery by the truck. .

Embodiment 2
In the second embodiment, it is assumed that when a product is loaded on the weight of each store, the manufacture of all the products to be loaded is completed. Since the configuration of the food system 1 and the hardware configuration of the sorting apparatus 10 in the second embodiment are the same as those in the first embodiment, description thereof is omitted. Moreover, since the process performed in the sorting apparatus 10 is the same as that of Embodiment 1 except for a part, in the following description, a different point is mainly demonstrated.

  24 and 25 are flowcharts showing an example of the procedure of the sorting process. In FIG. 24 and FIG. 25, the same processes as those shown in FIG. 4 and FIG. After selecting the processing store (step S2), the CPU 11 of the sorting apparatus 10 divides the products delivered to the selected store into categories (step S141). After setting a new weight (step S3), the CPU 11 selects a category of products to be processed (step S142). Here, the category is selected in the order of A, B, and C. In other words, the products are loaded from products that are not easily crushed. CPU11 reads the merchandise information about the goods of the selected category from the merchandise database 141 (step S143). CPU11 selects one of the goods contained in the selected category (step S144), and performs the process after step S7.

  When the processing of the selected product is completed, the CPU 11 determines whether or not there is another product not yet processed among the products included in the selected category (step S145). When the CPU 11 determines that there is another unprocessed product (YES in step S145), the CPU 11 performs the processing after step S12. If the CPU 11 determines that there is no other unprocessed product (NO in step S145), the CPU 11 determines whether there is an unprocessed category (step S146). If the CPU 11 determines that there is an unprocessed category (YES in step S146), the process returns to step S142.

  If the CPU 11 determines that there is no unprocessed category (NO in step S146), the CPU 11 rearranges the loading areas for each number based on the weight of the product (step S147). This rearrangement process is the same as the loading method instruction process shown in FIG. In step S127 of FIG. 21, sorting is performed by category, but in rearrangement processing, sorting is performed in descending order of weight. The CPU 11 outputs the loading method (similar to step S131 in FIG. 21). The CPU 11 determines whether there is an unprocessed store (step S15). If the CPU 11 determines that there is an unprocessed store (YES in step S15), the process returns to step S2. If the CPU 11 determines that there is no unprocessed store (NO in step S15), the process ends.

  The sorting apparatus 10 according to the second embodiment has the following effects. After all the products that should be loaded are collected, the loading position is determined for each category. Accordingly, it is possible to reliably load a product that is not easily crushed into a position on the front side of the truck in the weight, and to prevent a problem that the product is crushed during delivery. In addition, since sorting is performed by weight even within the same category, it is possible to more reliably suppress the occurrence of a problem that products are crushed during delivery.

  In Embodiments 1 and 2 described above, the number of product categories is three, but the present invention is not limited to this. The number of categories may be an arbitrary number of 2 or more. Moreover, although the category of goods is divided from the viewpoint of the degree of easy crushing, it is not limited thereto. It is also possible to categorize according to the weight of the product, and arrange the heavy product on the front and the light product on the back. As described above, as long as the product category is used when determining the arrangement of the product within the weight, other viewpoints can be adopted.

  Furthermore, in the above description, the product is a cooked food, but is not limited thereto. In the case where a plurality of types of products are mixedly loaded in a transport container such as a weight, and delivery is performed, the present invention can also be applied to cases where consideration must be given to the arrangement of products in the transport container.

  In the above description, the weight is a rectangular parallelepiped box, but the present invention is not limited thereto. The bottom plate may be oval or polygonal. In addition, the above-described algorithm for obtaining the number of products that can be loaded into the weight is an example. Other algorithms that can determine the number of products that can be loaded in order can also be employed. Furthermore, it may be appropriately changed according to the shape of the weight.

The technical features (components) described in each embodiment can be combined with each other, and new technical features can be formed by combining them.
The embodiments disclosed herein are illustrative in all respects and should not be considered as restrictive. The scope of the present invention is defined not by the above-mentioned meaning but by the scope of the claims, and is intended to include all modifications within the meaning and scope equivalent to the scope of the claims.

DESCRIPTION OF SYMBOLS 1 Food system 2 Store POS apparatus 3 Order management system 4 Food production system 5 Sorting system 6 Delivery service system 10 Sorting apparatus 11 CPU
12 ROM
13 RAM
14 Hard Disk 141 Product Database 142 Order Information Database 143 Loading Area Database 15 Disk Drive 16 Communication Unit 17 Display Unit 18 Operation Unit 10P Program (Computer Program)
10d optical disk 10m semiconductor memory 20 transport device

Claims (8)

In the sorting device that sorts the products based on the dimensions of the products and the number of orders and the weight of the goods,
A determination unit for determining the number of products loaded and the loading position for each weight;
A ranking unit that ranks the products for each weight according to the type of the product,
A sorting device, comprising: a changing unit that changes a loading position of the product determined by the determining unit so that the products are arranged in order of order along the predetermined direction of the weight. The determination unit
A single item determining unit that determines the number of loadings and the loading position for each product,
A determination unit for determining whether or not there is an empty space in the number after the single item determination unit finishes processing for one product;
2. The sorting apparatus according to claim 1, wherein, when the determination unit determines that there is an empty space, the single item determination unit determines the number of products to be loaded and the loading position in the empty space. The single-item determining unit determines the number of stacking steps so that the number of stacking steps is equal to or less than an allowable number of steps and the stacked height does not exceed the height dimension of the weight when the products are stackable. The sorting apparatus according to claim 1 or 2. The said single item determination part determines the said loading number and a loading position so that the clearance gap of a predetermined dimension may be ensured between the said goods and between the said goods and the surrounding wall of the said weight. The sorting apparatus according to claim 3. A first acquisition unit for acquiring identification information of a product to be loaded;
A second acquisition unit that acquires identification information of a product that has been manufactured and can be loaded;
When the identification information acquired by the second acquisition unit is included in the identification information acquired by the first acquisition unit, the processing by the determination unit, the ranking unit, and the change unit regarding the products that can be loaded is executed. The sorting apparatus according to any one of claims 1 to 4, wherein the sorting apparatus is characterized. When the identification information acquired by the second acquisition unit includes all the identification information acquired by the first acquisition unit, the processing by the determination unit, the ranking unit, and the change unit regarding the products that can be loaded is executed. The sorting apparatus according to claim 5, wherein: A computer that sorts products based on product dimensions, order quantity and weight
Determine the number and position of the product to be loaded for each weight.
According to the type of product, ranking the product for each number of weights,
A computer program for executing a process of changing the loading position of the product determined by the determination unit so that the products are arranged in order of order along a predetermined direction of the weight. In the sorting method in which the computer sorts the products based on the dimensions of the products, the order quantity and the weight of the goods,
Determine the number and position of the product to be loaded for each weight.
According to the type of product, ranking the product for each number of weights,
The sorting method of changing the loading position of the product determined by the determination unit so that the products are arranged in order of order along the predetermined direction of the weight.

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