JP2017182448A - Supply source and transportation means determination device, and supply source and transportation means determination system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To achieve inventory management that reflects business strategy of a company.SOLUTION: A supply source and transportation means determination device includes: a storage unit that stores accommodation fundamental data for accommodating a handling product among a plurality of footholds and company business strategy data representing company business strategy according to management principle and sales measures for sales and distribution of the handling product; an operation unit for determining a recommended supply source of the handling product and transportation means that reflects the company business strategy data based on the accommodation fundamental data; and a screen display unit for displaying a screen representing change in a stock status of the handling product when the handling product is accommodated among a plurality of footholds according to the transportation means and recommended supply source determined by the operation unit.SELECTED DRAWING: Figure 5

Description

  The present invention relates to a supply source and transportation means determination apparatus, and a supply source and transportation means determination system.

  In the maintenance parts business for construction machinery and mining machines, in recent years, with the progress of globalization, inventory bases are constructed in major regions of the world, and inventory management of tens of thousands of parts for each inventory base is performed. Conventional maintenance parts inventory management methods have a unidirectional supply chain structure in which maintenance parts are replenished only from a central warehouse to inventory bases around the world. For this reason, when replenishing inventory of maintenance parts at a certain inventory base, the maintenance parts are supplied from the central warehouse to the inventory base even if one of the other inventory bases has excess inventory of the same maintenance parts. The As a result, there is a problem in that the inventory amount in the entire supply chain increases.

  In order to solve the above problems, for example, the method of Patent Document 1 has been proposed. Japanese Patent Application Laid-Open No. 2004-151561 discloses a technique for centrally managing parts inventory held at each service base and placing and ordering parts between service bases.

JP 2003-141399 A

  In a business with a wide variety of products, such as maintenance parts business for construction machinery and mining machinery, in general, the amount of each product handled varies depending on the company's sales strategy. Therefore, it is preferable to perform inventory management that appropriately reflects the company's sales strategy. However, since the invention described in Patent Document 1 does not consider such points, inventory management that reflects the company's business strategy cannot be realized.

According to the first aspect of the present invention, the supply source and the means for transport means determine the basic data for the interchange of the handled products among a plurality of bases, and the management policy and the sales policy for the sales and distribution of the handled products. A storage unit for storing company sales strategy data representing the company sales strategy, and a calculation unit for determining a recommended supply source and transportation means of the handling product reflecting the company sales strategy data based on the interchangeable basic data, A screen display unit for displaying a screen representing a change in inventory status of the handled product when the handled product is accommodated between the plurality of bases according to the recommended supply source and the transportation means determined by the computing unit; Prepare.
According to the second aspect of the present invention, the supply source and transportation means determination system includes a plurality of user terminals and a supply source and transportation means determination device connected by a network. However, the supplier and the means for transport means determine the basic data for the interchange of the handled products among multiple bases, and the company sales strategy according to the management policy and the sales policies for the sales and distribution of the handled products. A storage unit that stores company sales strategy data to be represented, a calculation unit that determines a recommended supply source and transportation means of the handling product that reflects the company sales strategy data, based on the interchange basic data, and a determination by the calculation unit Stock status of the handled product when the handled product is interchanged among the plurality of bases in accordance with the recommended supply source and means of transportation. An information output unit that outputs information for displaying a screen representing a change in the information to the plurality of user terminals, and the user terminal displays the screen based on the information output from the information output unit A user terminal display unit is provided.

  According to the present invention, it is possible to realize inventory management reflecting the company's business strategy.

It is a figure which shows an example of the supply chain which the supplier and the transportation means determination apparatus make object. It is a figure which shows the structure of the supply source and transport means determination system containing the supply source and transport means determination apparatus. It is a block diagram which shows the hardware constitutions of the supply source and the transportation means determination apparatus. It is the figure which visualized the information memorize | stored in the data storage part 210 while expressing the function with which a supply source and the transportation means determination apparatus 200 are provided as a functional block. It is a flowchart showing the process which the recommended supply source and the transportation means determination part 221 perform. FIG. 6 is a diagram illustrating an example of a recommended supply source and transportation means when parts A to M are supplied to the inventory base A. It is a figure which shows an example of the some supply pattern enumerated exhaustively. It is a figure which shows an example of the stock information 211. It is a figure which shows an example of the order information. It is a figure which shows an example of the management policy information 213. It is a figure which shows an example of the sales measure information 214. It is a figure which shows an example of the component information 215. It is a figure which shows an example of LT information 216. FIG. It is a figure which shows an example of the cost coefficient information 217. It is a figure which shows an example of the transportation cost information 218. It is a figure which shows an example of the recommended supply information 219. It is a figure which shows an example of stock information 2110 after supply. It is a figure which shows an example of the display to the screen display part 240. FIG. In 2nd Embodiment, it is a flowchart showing the process which the recommended supply source and the transportation means determination part 221 perform. 14 is a flowchart illustrating processing executed by a recommended supply source and transportation means determination unit 221 in the third embodiment.

(First embodiment)
Hereinafter, with reference to FIGS. 1-18, 1st Embodiment of the supplier and the transportation means determination apparatus which concern on this invention is described. In the first embodiment described below, an example of an apparatus that determines a supply source and a transportation means when replenishing inventory of maintenance parts, which are handled products, in a supply chain of a maintenance parts business of a construction machine or a mining machine. Explained.

  FIG. 1 is a diagram illustrating an example of a supply chain targeted by a supply source and transportation means determination apparatus according to the present embodiment. This supply chain includes three sales agents indicated by reference numerals 106 to 108 for selling maintenance parts to customers, that is, a sales agent A, a sales agent B, and a sales agent C. Further, an order is received from each sales agent, and three stock bases indicated by reference numerals 103 to 105 for supplying parts to the respective sales agents, that is, stock base A, stock base B, and stock base C are set. Including. Further, a central warehouse 102 having a function of supplying maintenance parts to three inventory bases is included. In the following description, the inventory bases A, B, and C and the central warehouse 102 may be simply referred to as “base”.

  The central warehouse 102 can purchase desired maintenance parts from the maintenance parts supplier 101. For transportation of parts from the central warehouse 102 to the three inventory bases and transportation of parts between the three inventory bases, any one of a plurality of transportation means can be used.

  The supply source and transportation means determination apparatus according to the present embodiment uses which transportation means from any of the other stock bases and the central warehouse 102 to supply maintenance parts to be replenished to each of the three stock bases in the supply chain of FIG. Decide how many to supply. However, below, the case where the stock replenishment of the stock base A among the three stock bases is performed will be described as a representative example. That is, in the following, a method for determining how many maintenance parts to be replenished to the stock base A from each base of the stock base B, the stock base C, and the central warehouse 102 and using which transportation means is supplied will be described.

  FIG. 2 is a diagram illustrating a configuration of a supply source and transportation means determination system 1 including the supply source and transportation means determination device 200 according to the present embodiment. The supply source and transport means determination system 1 includes a supply source and transport means determination device 200 and a user terminal 402 provided in the central warehouse 102, a user terminal 403 provided in the inventory base A, and a user terminal provided in the sales agency A. 406, a user terminal 404 provided in the inventory base B, a user terminal 406 provided in the sales agency B, a user terminal 405 provided in the inventory base C, a user terminal 408 provided in the sales agency C, and the head office And a user terminal 409 provided in the function 109. The head office function 109 is an organization that formulates a corporate strategy for sales and distribution of maintenance parts by the supplier and transport means determination system 1 from the viewpoint of overall management and determines a management policy in accordance with the corporate strategy. In addition to the management policy determined by the head office function 109, each sales agent can individually formulate a sales strategy for sales of its own maintenance parts and determine a sales measure according to the sales strategy. .

  The supply source / transportation means determination apparatus 200 and the respective user terminals 403 to 409 are connected via the network 300. The user terminals 403 to 405 receive ordering information for each maintenance part at each base determined at the central warehouse 102 and the stock bases A, B, and C, respectively. Based on the ordering information input to the user terminals 403 to 405, the supply source and transportation means determination apparatus 200 calculates the inventory replenishment cost at each base for each maintenance part and the supply route, and inventory based on the calculation result. Determine the source and means of transportation at the time of replenishment. On the other hand, the sales measures determined by the sales agents A, B, and C are input to the user terminals 406, 407, and 408, respectively. In addition, the management policy determined by the head office function 109 is input to the user terminal 409. The supply source and transportation means determination apparatus 200 calculates the inventory replenishment cost at each base based on the sales policy of each sales agent input to the user terminals 406 to 408 and the management policy input to the user terminal 409. An adjustment coefficient for calculation is determined. In the present embodiment, the sales measure and the management policy are collectively referred to as a company sales strategy. Information input to each of the user terminals 403 to 409 can be read from the supply source and the transportation means determination apparatus 200 via the network 300.

  The user terminal 402 includes an input unit 451 that receives input from the user, and a user terminal display unit 452. The input unit 451 is a mouse, for example. The user terminal display unit 452 is a liquid crystal display, for example. The user inputs ordering information to the user terminal 402 using the input unit 451. The user terminal display unit 452 displays the calculation result transmitted from the supply source and transportation means determination apparatus 200. The other user terminals 403 to 409 have the same configuration as the user terminal 402. However, in the user terminals 406 to 408 respectively provided in the sales agents A, B, and C, the sales policy of each sales agent is input from the user using the input unit 451. Further, in the user terminal 409 provided in the head office function 109, a management policy is input from the user using the input unit 451.

  FIG. 3 is a block diagram illustrating a hardware configuration of the supply source and transportation means determination apparatus 200. The supply source / transport means determination device 200 stores a data storage unit 210 that stores data input to the supply source / transport means determination device 200, and performs predetermined arithmetic processing based on the data stored in the data storage unit 210. The calculation unit 220 to be executed, the output result of the calculation executed by the calculation unit 220 is recorded in the data storage unit 210 and the information is transferred to the screen display unit 240, and the output unit 230 outputs the information. And a screen display unit 240 for displaying information on a screen. The processing content of the arithmetic unit 220 will be described later with reference to the flowchart of FIG.

  The data storage unit 210 is a nonvolatile memory or a magnetic disk. The calculation unit 220 includes a CPU, a ROM, and a RAM. The CPU of the arithmetic unit 220 executes a process described later by expanding and executing a program stored in the ROM on the RAM. The output unit 230 includes a video output circuit and a data writing circuit. However, the functions realized by these circuits may be replaced by software.

  FIG. 4 is a diagram visualizing information stored in the data storage unit 210 while representing functions provided in the supply source and transportation means determination apparatus 200 as functional blocks.

  The calculation unit 220 includes a recommended supply source and transportation means determination unit 221 that performs a calculation based on data held by the data storage unit 210 as a function thereof. The recommended supply source and transport means determination unit 221 calculates a recommended supply part and a transport means of maintenance parts as a recommended supply pattern of maintenance parts between the bases when stocking the maintenance parts. Information obtained by this calculation is, for example, as shown in FIG. FIG. 6 shows an example of a recommended supply pattern when stocking the maintenance parts A to M at the inventory base A. In this recommended supply pattern, as shown in FIG. 6, a recommended supply source and transportation means are set for each maintenance part. As shown in FIG. 7, the recommended supply pattern has the lowest inventory replenishment cost among a plurality of supply patterns comprehensively listed for each combination of supply routes that can be taken when restocking each maintenance part. It is calculated as follows. Details will be described later with reference to FIG.

  The output unit 230 includes a recommended supplier and a transportation means output unit 231 as its functions. The recommended supply source and transportation means output unit 231 stores the calculation result of the calculation unit 220 in the data storage unit 210 as recommended supply information 219 described later and post-supply inventory information 2110 described later. Further, the recommended supply source and transportation means output unit 231 outputs the information stored in the data storage unit 210 to the screen display unit 240 and the user terminals 403 to 409. Information output to the user terminals 403 to 409 is performed via the network 300. An example of a screen displayed on the screen display unit 240 will be described later with reference to FIG.

  As shown in FIG. 4, the data storage unit 210 includes inventory information 211, order information 212, management policy information 213, sales policy information 214, parts information 215, and LT information 216 as lead time information. Cost coefficient information 217 used for cost calculation, transportation cost information 218, recommended supply information 219, which is a result of processing by the above-described calculation unit 220 and is information relating to a recommended supply source and transportation means, and recommended storage information 219 It is possible to store post-supply stock information 2110 that is the stock status of each base when the supply is performed as described. In the present embodiment, inventory information 211, order information 212, parts information 215, LT information 216, cost coefficient information 217, and transportation cost information 218 are collectively referred to as interchange basic data 210A, and management policy information. 213 and the sales measure information 214 are collectively referred to as company sales strategy data 210B. That is, the interchange basic data 210A is basic data for interchange of maintenance parts between a plurality of bases at the time of inventory replenishment. Further, the company sales strategy data 210B is data representing a company sales strategy corresponding to a management policy and a sales measure for the distribution of maintenance parts.

  Here, an example of the inventory information 211 is shown in FIG. 8, an example of the ordering information 212 is shown in FIG. 9, an example of the management policy information 213 is shown in FIG. 10, an example of the sales measure information 214 is shown in FIG. 12, FIG. 13 shows an example of LT information 216, FIG. 14 shows an example of cost coefficient information 217, FIG. 15 shows an example of transportation cost information 218, FIG. 16 shows an example of recommended supply information 219, An example of the inventory information 2110 is shown in FIG.

(Inventory information 211)
FIG. 8 is a diagram illustrating an example of the inventory information 211. The stock information 211 includes fields of an item 211-1, a base 211-2, an order point 211-3, a stock quantity 211-4, a surplus stock 211-5, and a stock unit price 211-6. The item 211-1 field stores the item of each maintenance part, that is, the name of each maintenance part. The name of each base is stored in the field of the base 211-2. In the inventory information 211 of FIG. 8, for each combination of maintenance parts and bases specified by these information stored in the fields of the item 211-1 and the base 211-2, the order point 211-3, the stock quantity 211- 4, information stored in each field of surplus stock 211-5 and stock unit price 211-6 is set. More specifically, the field of the order point 211-3 stores the number (number) of the maintenance parts that have already been ordered at the base. The field of the inventory quantity 211-4 stores the inventory quantity of the maintenance part at the base. The surplus inventory 211-5 field stores the surplus inventory number among the inventory numbers stored in the inventory number 211-4 field, that is, the number of items that are not scheduled to be sold or supplied to other locations for the time being. The The stock unit price 211-6 field stores the stock unit price of the maintenance part at the base.

(Ordering information 212)
FIG. 9 is a diagram illustrating an example of the order information 212. The order information 212 includes fields of an order base 212-1, an item 212-2, an order quantity 212-3, and a specified delivery date 212-4. The information stored in each of these fields is set based on the contents of the order each time the user places an order for maintenance parts from any base. The field of the order base 212-1 stores the name of the place where the order was placed. The field of the item 212-2 stores the item of the maintenance part to be ordered, that is, the name. The ordered quantity 212-3 field stores the quantity of ordered maintenance parts. In the field of the designated delivery date 212-4, the delivery date of the maintenance part designated by the order is stored. However, if no delivery date is designated, the field of designated delivery date 212-4 is blank.

(Management policy information 213)
FIG. 10 is a diagram illustrating an example of the management policy information 213. The management policy information 213 includes fields of a base 213-1, a policy 213-2, a retirement adjustment 213-3, a transportation adjustment 213-4, a warehouse adjustment 213-5, a procurement adjustment 213-6, and a selection 213-7. The The name of each base is stored in the field of the base 213-1. In the field of the policy 213-2, the name of the management policy that can be set in the head office function 109 is stored for each base stored in the field of the base 213-1. In the inventory information 211 of FIG. 10, for each combination of the base and the management policy specified by these pieces of information, the fields of the disposal adjustment 213-3, the transportation adjustment 213-4, the warehouse adjustment 213-5, and the procurement adjustment 213-6 are provided. The information stored in is set. Specifically, the fields of retirement adjustment 213-3, transport adjustment 213-4, warehouse adjustment 213-5, and procurement adjustment 213-6 include the management policy for calculating the inventory replenishment cost at the base. An adjustment coefficient that is a real number of 0 or more is stored in accordance with the corresponding weighting of each item. These adjustment factors are used to calculate inventory replenishment costs when determining sources and means of transport. All of these adjustment factors have a default value of 1.0. That is, according to the management policy in the head office function 109, when it is necessary to estimate a large amount of the cost, a large value is conversely, and when it is necessary to estimate the cost small, a small value is selected as the retirement adjustment 213-3, transportation The fields are input to the fields of adjustment 213-4, warehouse adjustment 213-5, and procurement adjustment 213-6. In the field of selection 213-7, a value of 0 or 1 is stored as a flag indicating the selection status for the combination of each base and management policy.

  In the present embodiment, information of fields other than the selection 213-7 is input in advance. When a management policy is input from the user terminal 409, the field of the row selection 213-7 corresponding to any one management policy is set to “1” for each site based on the input. Then, the base 213-1, the policy 213-2, the disposal adjustment 213-3, the transportation adjustment 213-4, the warehouse adjustment 213-5, and the procurement adjustment 213 in the row in which the field of the selection 213-7 is set to “1”. The value stored in each field of −6 is used in the above-described arithmetic unit 220. An arbitrary value can be input to each field of the management policy information 213 from the user terminal 409 based on the management policy determined by the head office function 109.

(Sales measure information 214)
FIG. 11 is a diagram illustrating an example of the sales measure information 214. Sales measure information 214 includes sales agent 214-1, policy 214-2, retirement adjustment 214-3, transportation adjustment 214-4, warehouse adjustment 214-5, procurement adjustment 214-6, selection 214-7, and jurisdiction inventory. It consists of the field of the base 214-8. The name of each sales agent is stored in the field of the sales agent 214-1. The field of the policy 214-2 stores the name of the sales measure that can be set for each sales agent stored in the field of the sales agent 214-1. In the sales measure information 214 of FIG. 11, as with the management policy information 213 of FIG. 10, the disposal adjustment 214-3, the transport adjustment 214-4, Information stored in each field of the warehouse adjustment 214-5, the procurement adjustment 214-6, and the selection 214-7 is set. The range of values entered in each of these fields, and the significance thereof, are respectively the retirement adjustment 213-3, transport adjustment 213-4, warehouse adjustment 213-5, procurement adjustment 213-6, and selection 213-7 in FIG. This is the same as the range of values entered in each field and their significance. That is, the replenishment adjustment 214-3, the transportation adjustment 214-4, the warehouse adjustment 214-5, the procurement adjustment 214-6, and the selection 214-7 are replenished at the inventory base corresponding to the sales agent. In accordance with the weighting of each expense according to the sales measure when calculating the cost, an adjustment coefficient that is a real number greater than or equal to 0 and has a default value of 1.0 is stored. In the field of selection 214-7, a value of 0 or 1 is stored as a flag indicating the selection status for each combination of sales agents and sales measures. Further, the field of the jurisdiction inventory base 214-8 stores information indicating which stock base is under the jurisdiction of each sales agent.

  In the present embodiment, in the data storage unit 210, information of fields other than the selection 214-7 in the sales measure information 214 shown in FIG. When the sales measure of each sales agent is input from the user terminals 406 to 408, based on the input, the field of the row selection 214-7 corresponding to any one sales measure for each sales agent is “1”. Set to The sales agent 214-1, the policy 214-2, the disposal adjustment 214-3, the transportation adjustment 214-4, the warehouse adjustment 214-5, and the line whose selection 214-7 field is set to “1”, and The value stored in each field of the procurement adjustment 214-6 is used in the above-described arithmetic unit 220. An arbitrary value can be input to each field of the sales measure information 214 from the user terminals 406 to 408 based on the sales measure determined by each sales agent.

(Part information 215)
FIG. 12 is a diagram illustrating an example of the component information 215. The parts information 215 includes fields of an item 215-1 and a supplier purchase unit price 215-2. The field of the item 215-1 stores the item of each maintenance part, that is, the name of each maintenance part. In the field of the supplier purchase unit price 215-2, the purchase unit price from the supplier 101 is stored for each maintenance part item stored in the item 215-1 field.

(LT information 216)
FIG. 13 is a diagram illustrating an example of the LT information 216. The LT information 216 includes items 216-1, transportation means 216-2, a supply source 216-3, a supply destination 216-4, and a field of LT 216-5 indicating supply lead time. The field of the item 216-1 stores the item of each maintenance part, that is, the name of each maintenance part. The name of the available transportation means is stored in the field of the transportation means 216-2. The field of the supply source 216-3 stores the name of each base that is the supply source of maintenance parts. The field of the supply destination 216-4 stores the name of each base that is the supply destination of the maintenance parts. In the LT information 216 of FIG. 13, the maintenance parts and the supply route specified by the information stored in the fields of the item 216-1, the transportation means 216-2, the supply source 216-3, and the supply destination 216-4, respectively. Information stored in the field of LT 216-5 is set for each combination. Specifically, in the field of LT 216-5, the item stored in the field of item 216-1 is stored in the field of supply destination 216-4 from the base stored in the field of supply source 216-3. The lead time, that is, the number of days in the case of transporting to the base by the transport means stored in the field of transport means 216-2 is stored.

(Cost factor information 217)
FIG. 14 is a diagram illustrating an example of the cost coefficient information 217. The cost coefficient information 217 includes fields of a base 217-1, a warehouse cost coefficient 217-2 used for obtaining a warehouse cost, and a disposal cost coefficient 217-3 used for obtaining a disposal cost. The name of each base is stored in the field of the base 217-1. In the warehouse cost coefficient 217-2 and the disposal cost coefficient 217-3, the ratio of the warehouse cost and the disposal cost to the inventory unit price of each maintenance part is stored for each base stored in the field of the base 217-1.

(Transportation cost information 218)
FIG. 15 is a diagram illustrating an example of the transportation cost information 218. The transportation cost information 218 includes fields of an item 218-1, transportation means 218-2, a supply source 218-3, a supply destination 218-4, and a transportation unit price 218-5. Information stored in the fields of the item 218-1, the transport means 218-2, the supply source 218-3, and the supply destination 218-4 is the item 216-1 and the transport means 216-2 in the LT information 216 of FIG. , Supply source 216-3 and supply destination 216-4, respectively. In the transportation cost information 218 of FIG. 15, the maintenance parts and the supply route specified by these items stored in the fields of the item 218-1, the transportation means 218-2, the supply source 218-3 and the supply destination 218-4, respectively. For each combination, information stored in the field of the transportation unit price 218-5 is set. Specifically, in the field of transportation unit price 218-5, the item stored in the field of item 218-1 is changed to the field of supplier 218-3 by the transportation means stored in the field of transportation means 218-2. The unit price for transporting from the base stored in the base to the base stored in the field of the supply destination 218-4 is stored.

(Recommended supply information 219)
FIG. 16 is a diagram illustrating an example of the recommended supply information 219. The recommended supply information 219 includes a supply pattern 219-1, an orderer 219-2, a supplier 219-3, a transportation means 219-4, an item 219-5, a specified delivery date 219-6, a supply LT 219-7 representing a lead time, Supply number 219-8, disposal cost 219-9, transportation cost 219-10, warehouse cost 219-11, procurement cost 219-12, total value 219-13, disposal adjustment 219-14, transportation adjustment 219-15, warehouse adjustment 219-16 and procurement adjustment 219-17. The field of the item 219-5 stores the item, that is, the name of the maintenance part to be restocked. In the fields of the supply pattern 219-1, the order source 219-2, the supply source 219-3, and the transport means 219-4, the recommended supply source and the transport means are determined for the maintenance parts stored in the field of the item 219-5. The recommended supply pattern calculated by the unit 221, the name of the ordering source and the base of the supply source in the recommended supply pattern, and the name of the transportation means are stored. In the fields of supply LT 219-7 and supply number 219-8, the lead time and the supply number of the maintenance parts stored in the field of item 219-5 are stored. That is, the recommended supply information 219 indicates that the recommended supply pattern specified by the value stored in the field of the supply pattern 219-1 is the most inventory replenishment cost with respect to the inventory replenishment of the maintenance parts stored in the field of the item 219-5. Indicates that the supply pattern is cheaper. In this recommended supply pattern, using the means stored in the field of the transportation means 219-4 from the base stored in the field of the supply source 219-3 to the base stored in the field of the order source 219-2, The maintenance parts stored in the field of the item 219-5 are supplied by the number stored in the field of the supply number 219-8. Note that the recommended supply pattern indicated by the recommended supply information 219 is one of a plurality of supply patterns listed exhaustively as described with reference to FIG.

(Breakdown of inventory replenishment costs)
In the fields of the disposal cost 219-9, the transportation cost 219-10, the warehouse cost 219-11, and the procurement cost 219-12, as the breakdown of the inventory replenishment cost of the maintenance parts in the above recommended supply pattern, the disposal cost and transportation Costs for each item of cost, warehouse cost, and procurement cost are stored. In the field of the total value 219-13, the sum of the costs for each item stored in the fields of the disposal cost 219-9, the transportation cost 219-10, the warehouse cost 219-11, and the procurement cost 219-12, that is, the recommended supply Stores the total inventory replenishment cost for the pattern. Below, the calculation method of the disposal cost in the recommended supply pattern which the recommended supply information 219 represents, transportation cost, warehouse cost, and procurement cost is demonstrated. For other supply patterns other than the recommended supply pattern, the cost for each of these items can be calculated by the same method.

(Calculation of destruction costs)
The disposal cost is calculated as follows. First, in the inventory information 211, a line in which the value of each field of the item 211-1 and the base 211-2 matches the maintenance part and the supply source in the supply pattern is specified, and the surplus inventory 211-5 of the line is identified. The value stored in the field reflects the supply number of maintenance parts in the supply pattern, that is, the value of the order quantity field 212-3 in the corresponding row in the order information 212, so that maintenance after supply at the supply source is performed. Update the excess inventory of parts. Next, the line corresponding to any combination of maintenance parts and bases is selected in the inventory information 211, and the field value of the surplus inventory 211-5 of the line is multiplied by the field value of the inventory unit price 211-6. Then, calculate the excess inventory cost of maintenance parts. At this time, the surplus inventory number updated as described above is used for the row corresponding to the combination of the maintenance part to be restocked and the base of the supplier. Next, in the cost coefficient information 217, a line in which the value of the field of the base 217-1 matches the value of the field of the base 211-2 of the line selected in the inventory information 211 is specified, and the maintenance component obtained above is identified. By multiplying the value of the surplus inventory cost by the value of the field of the disposal cost coefficient 217-3 of this row, the disposal cost of the maintenance parts before adjustment is obtained. Further, in the management policy information 213, the field value of the base 213-1 matches the field value of the base 211-2 in the row selected by the inventory information 211, and the field value of the selection 213-7 is “1”. ”Is identified, and the adjustment value of the disposal cost according to the management policy is obtained by referring to the value of the field of the disposal adjustment 213-3 of this row. Further, in the sales measure information 214, the value of the field of the jurisdiction stock base 214-8 matches the value of the field of the base 211-2 in the row selected by the stock information 211, and the value of the field of the selection 214-7 is By identifying the line “1” and referring to the value of the field of the retirement adjustment 214-3 of this line, the adjustment coefficient of the retirement cost due to the sales measure is obtained. Then, the disposal cost of the maintenance parts after the adjustment in consideration of the management policy and the sales policy is obtained by multiplying the disposal cost of the maintenance parts before the adjustment obtained above by these adjustment factors. This calculation is performed for all the maintenance parts including the maintenance parts for which the inventory is replenished, and all the inventory bases, and the sum of those parts is calculated to calculate the disposal cost.

  Specific examples for obtaining the disposal cost will be shown with reference to FIGS. 8, 10, 11, and 14. In the inventory information 211 shown in FIG. 8, since the inventory base B and the inventory base C have the surplus inventory for the part A, the two bases are calculated. The calculation is performed in the same manner for parts B and thereafter. Hereinafter, the disposal cost of the parts A at the inventory base B will be described in detail.

  The inventory base B which is the supplier of the part A has 50 surplus inventory of the part A, and from this, 10 of the supply numbers stored in the field of the supply number 219-8 of the recommended supply information 219 are in stock. Since it is supplied to the base A, the surplus inventory number of the parts A after the supply at the stock base B is 40. Next, the surplus inventory cost of the part A is calculated to be 12000 yen by multiplying the surplus inventory number of 40 parts A after supply by 300 yen that is the field value of the inventory unit price 211-6. Next, by multiplying the surplus inventory cost of 12,000 yen of the obtained part A by 20% that is the value of the field of the disposal cost coefficient 217-3 of the inventory base B in the cost coefficient information 217 shown in FIG. The cost of destroying part A is 2400 yen. Then, the disposal cost 2400 yen of the part A before adjustment obtained is 1.5 as the value of the field of the disposal adjustment 213-3 of the inventory base B in the management policy information 213 shown in FIG. 10, and FIG. By multiplying 1.2, which is the field value of the sales agent B's disposal adjustment 214-3 in the sales measure information 214, the disposal cost of the adjusted part A is calculated to be 4320 yen. Such calculation is also performed for other inventory bases and other parts, and the total value of all the calculated values is stored in the field of the disposal cost 219-9 as the disposal cost.

(Calculation of transportation costs)
The transportation cost is calculated as follows. First, in the transportation cost information 218, the values of the fields of the item 218-1, the transportation means 218-2, the supply source 218-3, and the supply destination 218-4 are the maintenance parts, transportation means, supply source, and By identifying a line that matches each supply destination and referring to the value of the field of transportation unit price 218-5 of this line, the transportation unit price of maintenance parts in the supply pattern is obtained. Next, the transportation cost before adjustment is obtained by multiplying the determined transportation unit price by the number of maintenance parts supplied in the supply pattern, that is, the value of the order quantity field 212-3 in the corresponding row in the order information 212. Ask. Further, in the management policy information 213, a line in which the field value of the base 213-1 matches the supply source in the supply pattern and the field value of the selection 213-7 is “1” is specified. By referring to the value of the field of transport adjustment 213-5, an adjustment coefficient for transport cost according to the management policy is obtained. Further, in the sales measure information 214, a line in which the field value of the jurisdiction inventory base 214-8 matches the supply source in the supply pattern and the field value of the selection 214-7 is “1” is specified, By referring to the value of the field of the retirement adjustment 214-4 in this row, the adjustment coefficient of the transportation cost by the sales measure is obtained. Then, the transportation cost before adjustment obtained above is multiplied by these adjustment factors to obtain the adjusted transportation cost considering the management policy and the sales measure. In this way, transportation costs are required.

  Specific examples of obtaining the transportation cost will be described with reference to FIGS. 9, 10, 11, and 15. In the recommended supply information 219 of FIG. 16, the part A is stored in the field of the item 219-5 as information representing the maintenance part, the transport means, the supply source, and the supply destination in the recommended supply pattern. Air mail is stored in the field, the stock base B is stored in the field of the supply source 219-3, and the stock base A is stored in the field of the order source 219-2. In the transportation cost information 218 shown in FIG. 15, the field value of the transportation unit price 218-5 corresponding to these, that is, the field of the item 218-1 is the part A, and the field of the transportation means 218-2 is the air mail. The value of the field of the transportation unit price 218-5 corresponding to the supply route in which the field of the supply source 218-3 is the inventory base B and the field of the supply destination 218-4 is the inventory base A is 1000 yen. The transportation unit price of the part A in the pattern is determined to be 1000 yen. Next, the transportation cost before adjustment is calculated to be 10,000 yen by multiplying the transportation unit price of 1000 yen by 10 that is the value of the number of supply 219-8 in the recommended supply information 219 shown in FIG. Then, the transport cost 10000 yen before adjustment obtained is set to 0.5 which is the value of the field of the transport adjustment 213-4 of the inventory base B in the management policy information 213 shown in FIG. 10, and the sales measure information shown in FIG. By multiplying by 1 which is the field value of the transportation adjustment 214-4 of the sales agent B in 214, the adjusted transportation cost is calculated as 5000 yen. The value calculated in this way is stored in the field of transportation cost 219-10 as transportation cost.

(Calculation of warehouse costs)
The warehouse cost is calculated as follows. First, in the inventory information 211, a line in which the values of the fields of the item 211-1 and the base 211-2 match the maintenance part and the supply source in the supply pattern is specified, and the inventory number 211-4 of the line is determined. The value stored in the field reflects the supply number of maintenance parts in the supply pattern, that is, the value of the order quantity field 212-3 in the corresponding row in the order information 212, so that maintenance after supply at the supply source is performed. Update the number of parts in stock. Further, the value of each field of the item 211-1 and the base 211-2 identifies a line that matches the maintenance part and the supply source in the supply pattern, and is stored in the field of the inventory quantity 211-4 of the line. By reflecting the value of the supply quantity of maintenance parts in the supply pattern, that is, the value of the order quantity field 212-3 of the corresponding line in the order information 212, the maintenance parts after supply at the order source (supply destination) are reflected in the value. Update inventory count for. Next, a line corresponding to any combination of maintenance parts and bases is selected in the inventory information 211, and the value of the field of the inventory quantity 211-4 in the line is multiplied by the value of the field of the inventory unit price 211-6. Then, determine the inventory cost of the maintenance parts. At this time, the number of inventory updated as described above is used for the row corresponding to the combination of the maintenance part to be restocked and the supplier or ordering base. Next, in the cost coefficient information 217, a line in which the value of the field of the base 217-1 matches the value of the field of the base 211-2 of the line selected in the inventory information 211 is specified, and the maintenance component obtained above is identified. By multiplying the value of the inventory cost by the value of the field of the warehouse cost coefficient 217-2 of the row, the warehouse cost of the maintenance part before adjustment is obtained. Further, in the management policy information 213, the field value of the base 213-1 matches the field value of the base 211-2 in the row selected by the inventory information 211, and the field value of the selection 213-7 is “1”. ”Is identified, and the warehouse cost adjustment coefficient according to the management policy is obtained by referring to the value of the field of warehouse adjustment 213-5 of this row. Further, in the sales measure information 214, the value of the field of the jurisdiction stock base 214-8 matches the value of the field of the base 211-2 in the row selected by the stock information 211, and the value of the field of the selection 214-7 is By identifying the line “1” and referring to the value of the field of warehouse adjustment 214-5 of this line, the adjustment coefficient of the warehouse cost due to the sales measure is obtained. Then, the warehouse cost of the maintenance parts after the adjustment in consideration of the management policy and the sales policy is obtained by multiplying the warehouse cost of the maintenance parts before the adjustment obtained above by these adjustment factors. This calculation is performed for all the maintenance parts including the maintenance parts for which the inventory is replenished, and all the inventory bases, and the sum of them is obtained, whereby the warehouse cost is calculated.

  Specific examples for obtaining the warehouse cost will be described with reference to FIGS. 8, 10, 11, and 14. In the inventory information 211 shown in FIG. 8, the inventory base B that is the supplier of the part A has 50 parts A in stock, and stores from here the supply number 219-8 field of the recommended supply information 219. Since 10 of the supplied numbers are supplied to the stock base A, the stock number of the parts A after the supply at the stock base B is 40. Next, the inventory cost of the part A is determined to be 12000 yen by multiplying the inventory quantity of 40 parts A after supply by 300 yen, which is the field value of the inventory unit price 211-6. Next, by multiplying the obtained inventory cost 12000 yen of the part A by 10% which is the value of the field of the warehouse cost coefficient 217-2 of the inventory base B in the cost coefficient information 217 shown in FIG. The warehouse cost of part A is required to be 1200 yen. Then, the obtained warehouse cost of 1200 yen for the part A before adjustment is 1.2 as the value of the field of warehouse adjustment 213-5 of the inventory base B in the management policy information 213 shown in FIG. By multiplying 1.8, which is the value of the field of the warehouse adjustment 214-5 of the sales agent B in the sales measure information 214, the warehouse cost of the adjusted part A is calculated to be 2592 yen. Such calculation is also performed for other inventory bases and other parts, and the total value of all the calculated values is stored as a warehouse cost in the field of warehouse cost 219-11.

(Calculation of procurement costs)
Procurement costs are calculated as follows. First, it is determined whether or not procurement of maintenance parts from the supplier 101 to the central warehouse 102 is performed by confirming whether or not the supply source in the supply pattern is the central warehouse. Next, when the maintenance parts are procured from the supplier 101 to the central warehouse 102, the value of the field of the item 211-1 matches the maintenance parts in the supply pattern in the inventory information 211, and the base 211- By identifying the row in which the value of the field 2 is the central warehouse and subtracting the value of the field of the surplus stock 211-5 of this row from the value of the field of supply number 219-8 of the recommended supply information 219, the inventory replenishment The number of newly procured maintenance parts from the supplier 101 is obtained. Note that if no maintenance parts are procured from the supplier 101 to the central warehouse 102, or if the obtained new procurement number becomes a negative value, the new procurement number from the supplier 101 is set to zero. Next, in the component information 215, a row in which the field value of the item 215-1 matches the maintenance component in the supply pattern is specified, and the supplier purchase unit price 215-2 of this row is added to the number of new procurements obtained above. Multiply the value of the field to obtain the procurement cost before adjustment. Further, in the management policy information 213, a line in which the field value of the base 213-1 is the central warehouse and the field value of the selection 213-7 is “1” is specified, and the procurement adjustment 213− of this line is specified. By referring to the value in field 6, the adjustment factor for procurement costs according to the management policy is obtained. And the procurement cost after adjustment which considered the management policy is calculated | required by multiplying the procurement cost before adjustment calculated | required above by this adjustment factor. In this way, procurement costs are required.

  Specific examples of obtaining procurement costs will be described with reference to FIGS. 8, 10, and 12. In the recommended supply information 219 of FIG. 16, as information indicating the maintenance parts and the number of supplies in the recommended supply pattern, the part A is stored in the field of the item 219-5, and the value of the field of the supply number 219-8 is 10. is there. Here, in the recommended supply information 219 of FIG. 16, the name of the base stored in the field of the supply source 219-3 is the inventory base B, and therefore the supply source of the recommended supply pattern is not the central warehouse. Therefore, the procurement cost of the recommended supply pattern is originally calculated as 0. However, in the following description, it is assumed that the supply source of the recommended supply pattern is the central warehouse. In this case, in the inventory information 211 shown in FIG. 8, since the surplus inventory number of the part A in the row where the central warehouse is stored in the field of the base 211-2 is 0, the number of parts having the same quantity as the supply number is 10 parts. A is newly procured from the supplier 101. By multiplying the number of newly procured 10 pieces by 100 yen which is the value of the field of the supplier A purchase price 215-2 of the part A in the part information 215 shown in FIG. 12, the procurement cost before adjustment is obtained as 1000 yen. Then, the procurement cost after adjustment is multiplied by 1.5, which is the field value of the procurement adjustment 213-6 of the central warehouse 102 in the management policy information 213 shown in FIG. The cost is calculated as 1500 yen. The value calculated in this way is stored in the field of the procurement cost 219-12 as the procurement cost.

(Stock information after supply 2110)
FIG. 17 is a diagram illustrating an example of post-supply stock information 2110. The post-supply stock information 2110 includes an item 2110-1, a base 2110-2, a pre-supply stock 2110-3, a pre-supply stock amount 2110-4, a pre-supply surplus 2110-5, a pre-supply surplus amount 2110-6, and an order point 2110. -7, stock after supply 2110-8, stock amount after supply 2110-9, surplus after supply 2110-10, surplus amount after supply 2110-11. The field of the item 2110-1 stores the item of each maintenance part, that is, the name of each maintenance part. The name of each base is stored in the field of the base 2110-2. In the post-supply stock information 2110 of FIG. 17, the pre-supply stock 2110-3, supply for each combination of maintenance parts and bases identified by these items stored in the fields of the item 2110-1 and base 2110-2, respectively. Pre-stock amount 2110-4, surplus before supply 2110-5, surplus amount before supply 2110-6, order point 2110-7, post-supply stock 2110-8, post-supply stock amount 2110-9, surplus after supply 2110-10, Information stored in each field of surplus after supply 2110-11 is set. It should be noted that the values of the corresponding fields in the inventory information 211 in FIG. Further, in the fields of the pre-supply stock amount 2110-4 and the pre-supply surplus amount 2110-6, the values of the fields of the pre-supply stock 2110-3 and the pre-supply surplus 2110-5 are set in the stock information 211 of FIG. The product of the corresponding inventory unit price 211-6 multiplied by the field value is stored. On the other hand, in the fields of the post-supply inventory 2110-8 and the surplus after supply 2110-10, the values of the fields of the pre-supply stock 2110-3 and the surplus before supply 2110-5 are supplied with the recommended supply information 219 of FIG. A value reflecting the value of the field of Formula 219-8 is stored. Further, in the fields of the post-supply stock amount 2110-9 and the post-supply surplus amount 2110-11, the values of the fields of the post-supply stock 2110-8 and the post-supply surplus 2110-10 are set in the stock information 211 of FIG. The product of the corresponding inventory unit price 211-6 multiplied by the field value is stored. The post-supply inventory information 2110 indicates the inventory fluctuation status of the maintenance parts at each base when the maintenance parts are supplied according to the recommended supply information 219. That is, when inventory replenishment is performed according to the recommended supply pattern, the number of inventory items stored in the item 2110-1 field of the inventory site stored in the field of the inventory site 2110-2 is the same as the inventory before supply 2110-3. The number stored in the field changes from the number stored in the field of the post-supply stock 2110-8.

(Recommended supplier and transportation means determination unit 221)
The processing contents of the recommended supply source and transportation means determination unit 221 that are functions of the calculation unit 220 will be described.

  FIG. 5 is a flowchart showing processing executed by the recommended supply source and transportation means determination unit 221. The execution subject of each step described below is the CPU of the arithmetic unit 220 shown in FIG. The calculation unit 220 executes the following processing every predetermined time, for example, every second.

  In step S100a, it is determined whether there is an order from any of the inventory bases. If it is determined that there is an order, the process proceeds to step S101. If it is determined that there is no order, the flowchart shown in FIG. In the following, a case where a part A is ordered from the stock base A will be described as an example.

  In step S <b> 101, information based on input data from the user is stored in the data storage unit 210. Specifically, the current ordering information at the inventory base A input from the user terminal 403 is stored in each corresponding field of the ordering information 212. Next, the process proceeds to step S102.

  In step S102, accommodation basic data 210A including the ordering information stored in step S101 is read from the data storage unit 210 into the RAM of the calculation unit 220, and the process proceeds to step S103.

  In step S103, all supply patterns that can be assumed for the part A are comprehensively generated based on the interchange basic data 210A read into the RAM of the arithmetic unit 220. Here, all the supply patterns that can be assumed are within the range of the number of parts A held by each of the central warehouse 102, the inventory base B, and the inventory base C. This is a combination of all means of transportation and the number of supplies that can be taken when A is the supply destination. In other words, each supply pattern generated defines how many parts A are supplied by which transportation means the inventory base A from each other base. Next, the process proceeds to step S105.

In step S105, the disposal cost, the transportation cost, the warehouse cost, and the procurement cost are calculated for each supply pattern generated in step S103 by the calculation method described above. Then, the sum of the disposal cost, transportation cost, warehouse cost, and procurement cost is used as the inventory replenishment cost of the supply pattern. This inventory replenishment cost represents the effect of accommodation in terms of cost when the part A is accommodated between a plurality of bases according to the supply pattern. Next, the process proceeds to step S104b.
In step S104b, it is determined whether or not the calculation of the accommodation effect, that is, the inventory replenishment cost is completed for all supply patterns. If it is determined that calculation has not been completed for all supply patterns, the process returns to step S105 to calculate the inventory replenishment cost for the next supply pattern. If it is determined that calculation has been completed for all supply patterns, the process returns to step S106. move on.

  In step S106, the supply pattern with the smallest inventory replenishment cost calculated in step S105, in other words, the supply pattern with the greatest flexibility effect is selected as the recommended supply pattern. Then, using the output unit 230, information of the selected recommended supply pattern, that is, the pattern number of the supply pattern, ordering source, supply source, transportation means, item, designated delivery date, supply lead time, number of orders, disposal cost, Each information of transportation cost, warehouse cost, procurement cost, total value, rejection adjustment coefficient, transportation adjustment coefficient, warehouse adjustment coefficient, and procurement adjustment coefficient is recorded as recommended supply information 219 in the data storage unit 210. Note that the information that the data storage unit 210 records as the recommended supply information 219 in step S106 is not limited to the supply pattern information with the minimum inventory replenishment cost. For example, a predetermined number of supply patterns may be selected as recommended supply patterns in ascending order of inventory replenishment costs, and information on each recommended supply pattern may be recorded as recommended supply information 219. Next, the process proceeds to step S107.

  In step S107, the stock status such as the number of parts A in stock and the surplus stock in each stock base and the central warehouse 102 when the supply is performed according to the recommended supply pattern selected in step S106 is calculated by the method described above. . Based on these calculated stock statuses, items, inventory bases, pre-supply inventory numbers, pre-supply inventory values, pre-supply surplus inventory numbers, pre-supply surplus inventory values, reorder points, post-supply inventory numbers, post-supply inventory Information on the amount of money, the number of surplus stock after supply, and the amount of surplus stock after supply is recorded in the data storage unit 210 as stock information 2110 after supply. Next, the process proceeds to step S108.

  In step S108, based on the recommended supply information 219 and the post-supply inventory information 2110 recorded in the data storage unit 210 in steps S106 and S107, the recommended supply source and transportation means of the part A in the recommended supply pattern, and the recommended supply pattern The change in the inventory status at each base when the part A is interchanged among a plurality of bases is displayed. Here, a screen display is performed on the screen display unit 240 of the supply source and transportation means determination apparatus 200 via the output unit 230, and a screen display is displayed on the user terminal 403 of the stock base A which is the ordering source of the part A. Information for displaying the same screen as that of the unit 240 is output. Further, the output unit 230 causes the user terminal 403 to display a display prompting ordering according to the recommended supply pattern. The ordering instruction in this step may be confirmed and confirmed by a person, or the calculation unit 220 may automatically place an order according to the recommended supply pattern. The program of FIG. 5 is complete | finished above.

  Note that the ordering instruction in step S108 includes not only the user terminal 403 of the inventory base A that placed the order, but also the user terminal 404 of the stock base B that is the recommended supply source, the user terminal 402 of the central warehouse 102 and the head office function 109, 409 may be displayed. Thereby, information can be shared between each base.

  When a person confirms and confirms the ordering instruction based on step S108, or when an order is automatically placed by the calculation unit 220, the calculation unit 220 updates the inventory information 211 based on the order.

(Screen display)
The display on the screen display unit 240 in step S108 described above will be described.
FIG. 18 is a diagram illustrating an example of a screen displayed on the screen display unit 240 in step S108 described above. As shown in FIG. 18, the recommended supply source and transportation means of the maintenance parts in the recommended supply pattern, and the change in the inventory status at each base when the maintenance parts are interchanged between a plurality of bases according to the recommended supply pattern On the display unit 240, for example, the screen is displayed over four columns described below.

The first column includes an order base display unit 240-1, an item display unit 240-2, a supply source display unit 240-3, a supply number display unit 240-4, a transportation means display unit 240-5, and a designated delivery date display unit. 240-6 and a procurement LT display unit 240-7. Among these, only the order base display unit 240-1 and the item display unit 240-2 can be selected by the user, and the display of some other display columns is changed based on the selection of these two columns.
The order base display unit 240-1 displays the stock base selected by the user, that is, the stock base of the supply destination for which the user wants to check the information of the recommended supply source and the transportation means. In the example of FIG. 18, the inventory base A is selected.

  In the item display section 240-2, an item selected by the user, that is, an item of a maintenance part for which the user wants to confirm information on the recommended supply source and the transportation means is displayed. In the example of FIG. 18, the part A is selected. The user selects an inventory base of a supply destination in the order base display unit 240-1 and selects a maintenance part item in the item display unit 240-2, thereby making the inventory status change display target in the screen of FIG. A recommended supply pattern can be selected.

  The supply source display unit 240-3, the supply number display unit 240-4, the transportation means display unit 240-5, and the designated delivery date display unit 240-6 include the supply source inventory base and maintenance parts in the selected recommended supply pattern. Supply number, transportation means, and specified delivery date from the ordering party are displayed. These contents are determined based on the values of the fields of the supply source 219-3, the order quantity 219-8, the transportation means 219-4, and the specified delivery date 219-6 of the recommended supply information 219 for the selected recommended supply pattern. The

  The procurement LT display section 240-7 displays the lead time, that is, the number of days until the maintenance parts reach the supplier. These values are determined based on the values of the supply LT 219-7 field of the recommended supply information 219 for the selected recommended supply pattern. Note that, as shown in parentheses of the procurement LT display unit 240-7 in FIG. 18, the estimated arrival date may be displayed by adding the value of the field of the supply LT 219-7 to the date at the time of ordering.

  The second column is composed of an inventory status display section 240-8. The stock status display section 240-8 is subdivided into a pre-supply stock status display section 240-8-1 and a post-supply stock status display section 240-8-2.

  The pre-supply stock status display section 240-8-1 displays the stock status of the maintenance parts at each site before supplying the maintenance parts according to the selected recommended supply pattern, that is, the current stock status. Here, based on the field values of the pre-supply inventory 2110-3 and the pre-supply surplus inventory 2110-5 of the post-supply inventory information 2110 for the part A selected in the item display unit 240-2, the supply at each base is performed. The stock quantity and surplus stock representing the stock status of the previous part A are displayed in a graph. As the inventory status of the parts A before supply, based on the field values of the pre-supply inventory amount 2110-4 and the pre-supply surplus amount 2110-6, the current inventory amount and surplus amount of the parts A at each base are calculated. It may be displayed.

  The post-supply stock status display section 240-8-2 displays the stock status of the maintenance parts at each site after the maintenance parts are supplied according to the selected recommended supply pattern. Here, after the supply at each base, based on the field values of the post-supply inventory 2110-8 and post-supply surplus 2110-10 of the post-supply inventory information 2110 for the part A selected by the item display unit 240-2 The stock quantity and surplus stock representing the stock status of the part A are displayed in a graph. In addition, as the inventory status of the part A after supply, the inventory amount and surplus amount after supply of the part A at each base are determined based on the field values of the post-supply stock amount 2110-9 and the post-supply surplus amount 2110-11. May be displayed.

  The third column includes a central warehouse management policy display unit 240-9, a management policy display unit 240-10 of the supplier stock base, and a sales measure display unit 240-11 of the sales agent.

  In the central warehouse management policy display section 240-9, the management policy for the central warehouse 102 is displayed. This content is determined based on the field value of the policy 213-3 in the row where the field of the base 213-1 of the management policy information 213 is the central warehouse and the field value of the selection 213-7 is 1. .

  The management policy display section 240-10 of the supply source inventory base displays the management policy of the inventory base that supplies the ordering base in the selected recommended supply pattern. In the example shown in FIG. 18, the inventory base A is selected in the order base display section 240-1, and the stock base B is selected in the supply source display section 240-3. Therefore, the content displayed in the management policy display section 240-10 of the supplier stock base is a line in which the base 213-1 field of the management policy information 213 is the stock base B and the selection 213-7 field is 1. It is determined based on the field value of the policy 213-2.

  The sales agent display unit 240-11 of the sales agent displays the sales agent policy information associated with the inventory base that supplies the ordering base in the selected recommended supply pattern. In the example shown in FIG. 18, the inventory base A is selected in the order base display section 240-1, and the stock base B is selected in the supply source display section 240-3. Therefore, the contents displayed in the sales measure display section 240-11 of the sales agent are that the field of the jurisdiction stock base 214-8 of the sales measure information 214 is the stock base B, and the field of the base 214-1 is the sales agent. B, which is determined based on the value of the field of the policy 214-2 of the row whose selection 214-7 field is 1.

  The fourth column includes a recommended supply pattern display unit 240-12. The recommended supply pattern display section 240-12 displays the inventory replenishment cost and its breakdown in the selected recommended supply pattern, and the adjustment coefficient for each expense item. The content is that the recommended supply pattern information corresponding to the order base selected by the order base display unit 240-1 and the item selected by the item display unit 240-2 is extracted from the recommended supply information 219. Determined by. In the example shown in FIG. 18, the inventory base B is selected in the order base display section 240-1, and the part A is selected in the item display section 240-2. Therefore, the content displayed in the recommended supply pattern display section 240-12 includes the supply of the row in which the field of the order source 219-2 of the recommended supply information 219 is the inventory base A and the field of the item 219-5 is the part A. Pattern 219-1, disposal cost 219-9, transportation cost 219-10, warehouse cost 219-11, procurement cost 219-12, total value 219-13, disposal adjustment 219-14, transportation adjustment 219-15, warehouse adjustment 219 -16, procurement adjustment 219-17 is determined based on the value of each field. In addition, as a breakdown of the inventory replenishment cost, as shown in parentheses of the recommended supply pattern display unit 240-12 in the example shown in FIG. 18, the value of each cost before multiplication by each adjustment coefficient may be displayed.

  Note that, as described above, the information displayed on the screen display unit 240 may be browsed via the network 300 from the head office function 109, each inventory base, and each sales agent user terminal.

According to the first embodiment described above, the following operational effects are obtained.
(1) The supply source and transportation means determination device 200 is a maintenance unit that reflects the company sales strategy data 210B based on the data storage unit 210 in which the accommodation basic data 210A and the company sales strategy data 210B are stored, and the accommodation basic data 210A. A calculation unit 220 that determines a recommended supply pattern representing a recommended supply source and a transportation means of the component, and a stock status of the maintenance component when the maintenance component is accommodated between a plurality of bases according to the recommended determination pattern determined by the calculation unit 220 And a screen display unit 240 for displaying a screen as shown in FIG.
Therefore, inventory management that reflects the company's sales strategy can be realized.

(2) In step S105, the calculation unit 220 calculates procurement costs, transportation costs, disposal costs, and warehouse costs before adjustment when maintenance parts are accommodated between a plurality of bases based on the basic accommodation data 210A. . Then, by adjusting these calculated costs based on the adjustment coefficient of each cost represented by the company sales strategy data 210B, procurement cost 219-12, transportation cost 219-10, disposal cost 219-9, and The warehouse cost 219-11 is calculated, and the inventory replenishment cost corresponding to the accommodation effect when maintenance parts are accommodated between a plurality of bases is calculated. Based on the flexibility effect calculated in this way, that is, the inventory replenishment cost, a recommended route pattern is determined in step S106.
Therefore, it is possible to replenish inventory from suppliers and transportation means with high flexibility, and it is possible to effectively use surplus inventory while reducing costs.

(3) The interchange basic data 210A includes stock information 211 including a stock quantity 211-4 representing the stock quantity of maintenance parts at a plurality of bases, and an order quantity 212 representing the number of maintenance parts ordered from any of the bases. Order information 212 including -3, transport cost information 218 including transport unit price 218-5 representing the transport cost of maintenance parts for each means of transportation between a plurality of bases, and supplier purchase unit price 215 representing the purchase unit price of maintenance parts Component information 215 including -2, and cost coefficient information 217 including maintenance component retirement cost information 217-3 and warehouse cost information 217-2 at a plurality of bases. The calculation unit 220 includes procurement information 219-12, transportation cost 219-10, disposal cost 219-9, and warehouse cost 219-11, inventory information 211, order information 212, transportation cost information 218, parts information 215, and cost. Calculation is performed based on the coefficient information 217. Specifically, the calculation unit 220 calculates a procurement cost 219-12 based on the inventory information 211 and the parts information 215, calculates a transportation cost 219-10 based on the transportation cost information 218 and the order information 212, A retirement cost 219-9 is calculated based on the information 211, the order information 212, and the cost coefficient information 217, and a warehouse cost 219-11 is calculated based on the inventory information 211, the order information 212, and the cost coefficient information 217. Since it did in this way, the inventory replenishment cost can be accurately calculated for each breakdown.

(4) The supply source and transportation means determination apparatus 200 includes an information output unit that outputs information for displaying a screen as shown in FIG. The supply source and transportation means determination device 200 is provided in the user terminals 403 to 405 provided in the stock bases A to B, the user terminals 406 to 408 provided in the sales agents A to C, and the head office function 109. It is connected to the user terminal 409 via the network 300. The output unit 230 outputs the above information to these user terminals. Further, the company sales strategy data 210B is input from the user terminals 406 to 409.
Therefore, refer to the calculation results of the supply source and transportation means determination device 220 even at a location different from the central warehouse 102 where the supply source and transportation means determination device 220 is installed, that is, the inventory base, the sales agent, and the head office function 109. Can do.

(5) The supply source and transport means determination system 1 includes a plurality of user terminals 403 to 409 and a supply source and transport means determination apparatus 200 connected by a network 300. The supplier and transport means determination apparatus 200 includes the data storage unit 210, the calculation unit 220, and the output unit 230 described above. The user terminals 403 to 409 include a user terminal display unit 452 that displays a screen as shown in FIG. 18 based on the information output from the output unit 230. Therefore, inventory management that reflects the company's sales strategy can be realized.

(Modification 1)
In the first embodiment described above, the method of calculating the inventory replenishment cost for each supply pattern for all the components at all the inventory bases has been described. However, the difference in inventory replenishment cost for each supply pattern with respect to this reference value may be calculated using the inventory replenishment cost in any supply pattern as a reference value. For example, the stock replenishment cost in the supply pattern 1 for supplying all the ordered parts from the central warehouse 102 is used as a reference value, and the stock replenishment cost for each supply pattern is different from the stock replenishment cost in the supply pattern 1 as the reference value. Calculate with Then, based on the difference of the inventory replenishment cost with respect to the reference value calculated for each supply pattern, the supply source and the transportation means of the handled product in the supply pattern with the smallest inventory replenishment cost are determined as the recommended supply source and the transportation means.
According to the first modification, in addition to the operational effects of the first embodiment, the following operational effects are achieved.

(1) The calculation unit 220 selects one of a plurality of bases as a supply source of handled products, and stocks in a supply pattern when one of a plurality of transportation means from the supply source to another base is selected. Using the replenishment cost as a reference value, the difference of the inventory replenishment cost with respect to the reference value in another supply pattern is calculated. Then, based on the difference between the inventory replenishment costs calculated for each supply pattern, the recommended supply source and the transportation means are determined.
Therefore, calculation of inventory replenishment costs can be omitted for inventory common to each supply pattern, and the amount of calculation can be reduced.

(Modification 2)
The disposal cost and the warehouse cost may be calculated only for the ordered part. In this case, for example, if the order is only for the part A, the disposal cost and the warehouse cost are also calculated only for the parts A at all the inventory bases.
According to the second modification, it is possible to omit the calculation for parts that are not ordered and whose inventory does not change.

(Modification 3)
The supply source and transportation means determination apparatus 200 may perform processing by directly reading the accommodation basic data 210A from the data storage unit 210. That is, the processing of step S102 in FIG. 5 may be omitted, and the basic accommodation data 210A may be read from the data storage unit 210 instead of the RAM of the calculation unit 220 in step S103.

(Second Embodiment)
With reference to FIG. 19, a second embodiment of the supply source and transportation means determination device will be described. In the following description, the same components as those in the first embodiment are denoted by the same reference numerals, and different points will be mainly described. Points that are not particularly described are the same as those in the first embodiment. The present embodiment is different from the first embodiment in that it does not mainly calculate the flexibility of supply patterns that do not meet the specified delivery date.

  The hardware configuration of the supply source and transportation means determination apparatus 200 in the second embodiment is the same as that in the first embodiment. The program stored in the ROM of the arithmetic unit 220 is different from that in the first embodiment.

  FIG. 19 is a flowchart showing processing executed by the recommended supply source and transportation means determination unit 221 in the second embodiment. The difference between FIG. 5 which is a flowchart showing the processing executed by the recommended supply source and transportation means determination unit 221 in the first embodiment and FIG. 19 is that FIG. 19 further executes step S109.

In step S109, which is executed after step S103, it is determined whether or not the delivery of the maintenance part in the supply pattern is in time for the designated delivery date. Specifically, whether the estimated arrival date obtained by adding the value of the LT216-5 field of the LT information 216 to the date of order placement is less than or equal to the value of the specified delivery date 212-4 field of the ordering information 212 Judge whether or not. As a result, if the estimated arrival date is less than or equal to the value in the field of the designated delivery date 212-4, that is, if it is earlier than or the same date as the delivery date, it is determined that the designated delivery date is met and the process proceeds to step S105. On the other hand, if the estimated arrival date is larger than the value in the field of the designated delivery date 212-4, that is, if it is later than the delivery date, it is determined that the designated delivery date is not met, and the process proceeds to step S104b to evaluate the next supply pattern. Move on. In this case, the calculation unit 220 excludes the supply pattern from the inventory replenishment cost, that is, the calculation target of the accommodation effect, by not executing Step S105 for the supply pattern.
Since the process after step S104b is the same as that of the first embodiment, the description thereof is omitted.

According to the second embodiment described above, the following operational effects can be obtained.
In other words, since the flexibility of supply patterns that do not meet the specified delivery date is not calculated, the procurement cost and the transportation cost are reduced as in the first embodiment while reducing the amount of calculation compared to the first embodiment. Considering disposal costs and warehouse costs, headquarters functions or central warehouse management policies and sales agency measures, it is possible to replenish inventory from suppliers and transportation means with high flexibility, reducing surplus while reducing costs Effective use of inventory.

(Third embodiment)
With reference to FIG. 20, a third embodiment of the supply source and transportation means determination device will be described. In the following description, the same components as those in the first embodiment are denoted by the same reference numerals, and different points will be mainly described. Points that are not particularly described are the same as those in the first embodiment. This embodiment is different from the first embodiment mainly in that different optimization methods are used.

  The hardware configuration of the supply source and transportation means determination apparatus 200 in the third embodiment is the same as that in the first embodiment. The program stored in the ROM of the arithmetic unit 220 is different from that in the first embodiment.

  FIG. 20 is a flowchart showing processing executed by the recommended supply source and transportation means determination unit 221 in the third embodiment. The difference between FIG. 5 and FIG. 20 that is a flowchart showing the processing executed by the recommended supply source and transportation means determination unit 221 in the first embodiment executes step S110 instead of steps S103 to S104b in FIG. Is a point.

  In step S110, which is executed after step S102, a supply pattern with the lowest cost, that is, the highest flexibility effect is calculated using a known optimization method such as a branch and bound method. Next, the process proceeds to step S106. Since the processing after step S106 is the same as that in the first embodiment, the description thereof is omitted.

According to the third embodiment described above, the following operational effects can be obtained.
That is, by adopting a known optimization method, while reducing the amount of calculation, as in the first embodiment, procurement costs, transportation costs, disposal costs, warehouse costs, and management of the head office function or central warehouse Considering the policy and measures of the sales agent, it is possible to replenish inventory from suppliers and transportation means with high flexibility, and it is possible to effectively use surplus inventory while reducing costs.

(Fourth embodiment)
A fourth embodiment of the supply source and transportation means determination device will be described. In the following description, the same components as those in the first embodiment are denoted by the same reference numerals, and different points will be mainly described. Points that are not particularly described are the same as those in the first embodiment. This embodiment differs from the first embodiment mainly in that a company sales strategy is determined for each part.

  The hardware configuration of the supply source and transportation means determination apparatus 200 in the fourth embodiment is the same as that in the first embodiment. The configuration of the fields of the management policy information 213 and the sales measure information 214 stored in the data storage unit 210 of the supply source and transportation means determination apparatus 200 is different from that of the first embodiment.

  In the fourth embodiment, the fields of the management policy information 213 and the sales measure information 214 have parts fields in addition to the fields of the first embodiment. That is, in the fourth embodiment, a management policy and a sales measure are set for each part. The point that the management policy is input from the user terminal 409 of the head office function 109 and the point that the sales measure is input from the user terminals 406 to 408 of the sales agents A to C are the same as in the first embodiment. .

  The recommended supply source / transport means determination unit 221 of the supply source / transport means determination apparatus 200 reads the input information, that is, in step S101 of the flowchart shown in FIG. 5, refers to the management policy information 213 and the sales measure information 214. The management policy and the sales measure are read for each part, and the processing from step S102 is executed.

  In each of the embodiments described above, maintenance parts of construction machines and mining machines have been described as examples of handling products for determining supply sources and transportation means in the supply chain. It may be a target. Further, the present invention may be applied not only to products sold to customers as final products, but also to products handled such as intermediate parts used for assembling final products. In other words, the present invention can be applied when determining supply sources and transportation means of products handled in supply chains of various fields and forms.

The above-described embodiments and modifications may be combined.
Although various embodiments and modifications have been described above, the present invention is not limited to these contents. Other embodiments conceivable within the scope of the technical idea of the present invention are also included in the scope of the present invention.

DESCRIPTION OF SYMBOLS 1 ... Transportation means determination system 109 ... Head office function 200 ... Supplier and transportation means determination apparatus 210 ... Data storage part 210A ... Interchange basic data 210B ... Company business strategy 211 ... Inventory information 212 ... Order information 213 ... Management policy information 214 ... Sales Measure information 215 ... Parts information 216 ... LT information 217-2 ... Warehouse cost coefficient 217-3 ... Destruction cost coefficient 218 ... Transportation cost information 220 ... Calculation part 240 ... Screen display part 300 ... Network 402 to 409 ... User terminal 451 ... Input Part 452 ... User terminal display part

Claims (9)

A storage unit that stores basic data on the interchange of handling products among a plurality of bases, and company sales strategy data representing a company sales strategy corresponding to a management policy and sales policies for sales and distribution of the handled products,
Based on the interchange basic data, a calculation unit that determines a recommended supply source and transportation means of the handling product reflecting the company business strategy data;
A screen display unit for displaying a screen representing a change in inventory status of the handled product when the handled product is accommodated between the plurality of bases according to the recommended supply source and the transportation means determined by the computing unit; A supplier and means for determining means of transportation. In the supply source and transportation means determination device according to claim 1,
The computing unit is
Based on the accommodation basic data, calculate procurement costs, transportation costs, disposal costs, and warehouse costs when the handling products are accommodated between the plurality of bases,
Based on the company business strategy data, by adjusting the procurement cost, the transportation cost, the disposal cost, and the warehousing cost, the flexibility effect when the handling product is interchanged among the plurality of bases is calculated. And
A supply source and transportation means determination apparatus that determines the recommended supply source and transportation means based on the accommodation effect. In the supply and transportation means determination device according to claim 2,
The interchange basic data includes inventory information representing the number of stocks of the handled products at the plurality of bases, ordering information representing the number of orders for the handled products from any of the plurality of bases, and the plurality of bases. Transportation cost information representing the transportation cost of the handled product for each transportation means, parts information representing the purchase unit price of the handled product, cost coefficient information representing the disposal cost and warehouse cost of the handled product at the plurality of bases, Including,
The calculation unit calculates the procurement cost, the transportation cost, the disposal cost, and the warehouse cost based on the inventory information, the order information, the transportation cost information, the parts information, and the cost coefficient information. Supplier and means of transport determination. In the supply source and transportation means determination device according to claim 3,
The computing unit is
Calculate the procurement cost based on the inventory information and the parts information,
Calculate the transportation cost based on the transportation cost information and the order information,
Calculate the disposal cost based on the inventory information, the order information and the cost coefficient information,
A supply source and transportation means determination device that calculates the warehouse cost based on the inventory information, the order information, and the cost coefficient information. In the supply source and transportation means determination device according to claim 3,
The accommodation basic data further includes lead time information indicating the transportation days of the handling product for each transportation means between the plurality of bases,
The ordering information further represents a delivery date of the handling product,
The calculation unit determines the recommended supply source and the transportation means by excluding the supply source and the transportation means not in time for the delivery date of the handled product based on the lead time information and the ordering information. Means determination device. In the supply and transportation means determination device according to claim 2,
The computing unit is
Selecting one of the plurality of bases as a supply source of the handling product, and using the flexibility effect in the supply pattern when selecting one of a plurality of transportation means from the supply source to another base as a reference value Calculating the difference of the accommodation effect with respect to the reference value in other supply patterns;
A supply source and transportation means determination apparatus that determines the recommended supply source and transportation means based on the difference between the accommodation effects calculated for each supply pattern. In the supply source and transportation means determination device according to claim 1,
The company sales strategy data is a supply source and transportation means determination device set for each item of the handled product. In the supply source and transportation means determination device according to claim 1,
An information output unit;
The supplier and the transportation means determination device are connected to a plurality of user terminals via a network,
The information output unit outputs information for displaying the screen to the user terminal,
The company sales strategy data is a supply source and transportation means determination device input from the user terminal. A supply source and transportation means determination system configured by a plurality of user terminals and a supply source and transportation means determination device connected by a network,
The supplier and the transportation means determination device are:
A storage unit that stores basic data on the interchange of handling products among a plurality of bases, and company sales strategy data representing a company sales strategy corresponding to a management policy and sales policies for sales and distribution of the handled products,
Based on the interchange basic data, a calculation unit that determines a recommended supply source and transportation means of the handling product reflecting the company business strategy data;
The plurality of pieces of information for displaying a screen representing a change in stock status of the handled products when the handled products are accommodated between the plurality of bases according to the recommended supply source and the transportation means determined by the calculation unit. An information output unit for outputting to the user terminal of
The user terminal is
A supplier and transportation means determination system comprising a user terminal display unit that displays the screen based on information output from the information output unit.

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