JP4175218B2 - Information processing method and computer system related to intermediate processing of waste - Google Patents

Description

  The present invention relates to information processing technology related to waste processing.

  In recent years, attention has been focused on the conservation of the global environment, and various laws have been developed. Among them, the Waste Disposal Law was amended in April 2001 to further strengthen the responsibilities of the dischargers, such as strengthening penalties for illegal dumping. In this law, it is obliged to manage waste with a management sheet called a manifest, and the following documents exist regarding information processing technology related to the management of this manifest.

In addition, as stipulated in the Basic Law for the Promotion of a Recycling-Oriented Society, companies must also control the generation of waste as a social responsibility, and only a manifest managed as a legal obligation alone disposes of the company. It is not enough for property management. In particular, in a company having a plurality of bases, it is necessary to grasp how much waste is discharged at which base and to take appropriate measures.
JP 2002-297758 A Japanese Patent Laid-Open No. 10-254947 JP 2000-264402 A JP 2002-80103 A

  As a method for reducing the amount of waste discharged in a company, there is a method in which an intermediate process is performed in the company, and the waste after the intermediate process is carried out to the outside of the company for final processing. Even if a company has a single base or multiple bases, each has an intermediate treatment facility, and each intermediate treatment facility does not carry out intermediate treatment of waste discharged from other bases Therefore, it is not difficult to grasp the amount of waste discharged at each site.

  However, when there is an intermediate treatment facility that collectively processes waste discharged from a plurality of bases, it is not always easy to grasp the amount of waste discharged from each base. For example, when sludge is collected from A, B, and C to A's intermediate process and incinerated, and the debris is carried out to the outside for final treatment, it is carried out from A that requires legal control by the manifest. It becomes burnt. As a matter of course, if only the manifest is managed, it is impossible to accurately grasp the amount of debris (final waste) at the bases A, B and C. In addition, it is not easy to prepare data for grasping the correspondence between debris and sludge from the timing of accepting sludge discharged by A, B and C, the timing of intermediate treatment, and the timing of carrying out the debris. .

  Here, simply consider a case in which the amount of debris discharged to the outside of the month is divided into A, B, and C by the ratio of the sludge treatment amount (= discharge amount) of each month. In FIG. 30, the result of apportionment is shown as the amount of generation for each month. Even if the intermediate treatment of sludge is carried out, the debris that is the result of the intermediate treatment is not always carried out immediately. Therefore, only 5 tons of C sludge was intermediately processed in December, but when 100 tons exceeding that amount were taken out for final treatment, C generated 100 tons of debris. End up. Therefore, as shown in the third row of the table in FIG. 30, the largest generation amount is allocated to C having an extremely small processing amount (= discharge amount) for the total for the year. Also, as shown on the far right of the third row, if the amount of export is apportioned based on the percentage of the annual processing amount, it seems to be a relatively reasonable distribution, but the timing of export has shifted from the previous year to this year. In some cases, or when the current year is shifted to the next year, the deviation from the actual situation will occur unnaturally. Another problem is that the results cannot be viewed until the end of the fiscal year.

  Therefore, an object of the present invention is to provide a novel information processing technique for enabling the waste after the intermediate treatment to be distributed at an appropriate ratio to the bases that have discharged the waste before the intermediate treatment.

  Another object of the present invention is to provide a novel information processing technique for enabling a comprehensive understanding of the state of waste discharge at each site.

  The present invention relates to an information processing method related to the intermediate treatment of waste in a company having a plurality of discharge bases, including waste weight data and waste base data of waste carried out of a company, and A first data storage unit that stores a record relating to waste is searched, and a distribution basic record (for example, data as shown in FIG. 17) that is a record for waste that has undergone intermediate processing is extracted and stored in a storage device. And a second data storage unit for storing a record including data of a discharge base of waste to be intermediately processed and data of waste weight before intermediate processing of waste discharged from the discharge base Based on the waste weight, one or more records corresponding to the distribution basic record stored in the storage device are intermediate processing records (for example, shown in FIG. 18). Intermediate processing record extraction step for extracting the stored waste in the distribution basic record by using the intermediate processing record extraction step for extracting the data as a data) and storing it in the storage device and the intermediate processing record stored in the storage device. And distributing the distribution result to each of the discharge bases in the distribution result storage unit.

  In this way, the second data storage unit that stores the record including the data of the discharge base of the waste that has been subjected to the intermediate treatment and the data of the waste weight before the intermediate treatment of the waste discharged from the discharge base is held. In addition, since the record corresponding to the distribution basic record for the waste that has been subjected to the intermediate processing is extracted based on the waste weight, the distribution to each discharge base can be performed with less error.

  The intermediate processing record extraction step described above includes a step of converting the waste weight in the distribution basic record into a waste weight before the intermediate processing and generating converted waste weight data, and a second data storage unit And a record group specifying step for specifying, as an intermediate process record, a record group from the specific record to the last record that accumulates the waste weight before intermediate processing in order and reaches the post-conversion waste weight. Also good. In this case, the waste weight in the distribution basic data is apportioned to each discharge base based on the waste weight before intermediate processing for each discharge base, which is totaled from the intermediate processing record. In addition, the waste weight before intermediate processing of the record stored in the second data storage unit may be converted to the waste weight after intermediate processing and then accumulated and compared with the waste weight in the allocation basic record. good. A table holding data of a conversion rate for conversion (a reduction coefficient in the embodiment) may be prepared and used.

  Further, in the record group specifying step described above, the records may be specified in order of date from the record next to the last record at the time of the previous processing, which is a specific record.

  Furthermore, when the record group identification step described above accumulates the waste weight before intermediate processing, if there is no record available before reaching the waste weight after conversion, the date is set in order from the last record. A step of accumulating the waste weight before the intermediate processing retroactively and specifying the group of records up to the record reaching the post-conversion waste weight may be further included as an intermediate processing record. For example, this step is performed as an exception process of the process described above.

  Further, in the present invention, when the final record exceeds the post-conversion waste weight, a record for the excess waste weight (before intermediate processing) may be generated and stored in the storage device. . Thereby, the error can be further reduced.

  Furthermore, in the present invention, using the database for managing the weight of waste after the intermediate processing and the second data storage unit, the date when the waste after the intermediate processing disappeared and the second data storage unit stored Cumulative waste weight from the last record is accumulated from the last record, and at least one of the days when the waste weight before intermediate treatment converted from the current waste weight obtained from the database is reached as the reference date The method may further include a step of specifying and storing the record of the reference date in the storage device as the specific record. Although a specific record is determined in a continuous process, an appropriate record may not be specified in the first process. In such a case, an appropriate “specific record” is automatically determined by performing the above processing.

  Further, in the present invention, the method further includes a step of calculating a waste processing cost based on the waste weight data of each discharge base stored in the distribution result storage unit and storing the expense in the distribution result storage unit. Also good. Not only the weight but also the cost will be apportioned.

  In addition, the data stored in the first data storage unit may be at least one of manifest data for industrial waste processing, data related to the manifest, and data for general waste processing. A simple configuration is also possible. The above-mentioned treatment is carried out for the waste that is subjected to the intermediate treatment. When the above treatment is also carried out for general waste, the waste at each discharge site can be grasped more accurately. Become.

  Further, in the present invention, when the collection of waste processing is instructed for a specific discharge base, records irrelevant to intermediate processing relating to the specific discharge base are extracted and aggregated from the first data storage unit and the distribution result is stored. You may make it further include the step which produces | generates total data by extracting and consolidating the record which concerns on a specific discharge base from a department, and storing it in a memory | storage device, and the step which outputs the total data stored in the memory | storage device. For example, the amount of waste from each discharge base can be properly grasped.

  Further, in the present invention, when the total disposal of waste is instructed for a specific discharge base, the specific discharge is received from the third data storage unit that stores data related to waste discharged by contract work contracted by another company. The method may further include a step of generating second aggregated data by extracting and aggregating data about the base, storing the data in the storage device, and outputting the second aggregated data stored in the storage device. . It becomes possible to appropriately grasp the amount of waste from each discharge base in a wider range.

  It is also possible to create a program for causing a computer to execute the information processing method according to the present invention, such as a flexible disk, a CD-ROM, a magneto-optical disk, a semiconductor memory, and a hard disk. It is stored in a storage medium or a storage device. The program or the like may be distributed as a digital signal via a network. Further, the data being processed is temporarily stored in the memory of the computer.

  According to the present invention, the waste after the intermediate treatment can be distributed at an appropriate ratio to the bases that have discharged the waste before the intermediate treatment.

  In addition, as another aspect of the present invention, it becomes possible to grasp the state of waste discharge at each base more comprehensively.

  FIG. 1 shows a system outline diagram according to an embodiment of the present invention. For example, a network 1 that is an in-house LAN (Local Area Network) includes one or a plurality of intermediate processing facility terminals 3 that are, for example, personal computers installed in an in-house intermediate processing facility for waste, and a base for carrying out waste to the outside. For example, one or a plurality of unloading base terminals 7 which are, for example, personal computers installed in a store / power plant / factory / business office, and an approver or other user who approves the total processing result of waste are operated. One or a plurality of in-house terminals 9 which are personal computers are connected to a server 5 which performs main processing in the present embodiment. Various terminals have a web browser function.

  The server 5 has a Web server function as an interface with various terminals connected to the network 1, and further performs a manifest data management unit 51 for managing manifest data and a registration process of various data. A data registration processing unit 52 for distribution, an apportioning processing unit 53 for performing apportionment processing for apportioning waste that has been intermediately processed in-house to each discharge base (discharge store), and a specific discharge base And a tally processing unit 55 for tallying data on waste. The manifest data management unit 51 is a data processing unit for managing a manifest in accordance with laws and regulations. In the present embodiment, only a portion related to the present embodiment will be described. The apportioning processing unit 53 includes an apportioning start data automatic determination processing unit 531 that performs processing for automatically determining the date or data on which the first apportioning process should be started.

  In addition, the server 5 stores various parameters for storing a table on the reduction rate (data indicating how much weight is reduced when the intermediate processing is performed) and a table of waste processing cost unit price. A storage unit 61, an intermediate processing amount data storage unit 62 that stores intermediate processing amount data input in intermediate processing amount registration described later, a manifest DB 63 that stores manifest data and its accompanying information, and an apportioning processing unit 53 Apportioning processing management table storage unit 64 for storing the apportioning processing management table to be used, intermediate processing aggregation DB 65 for storing the processing results of the apportioning processing unit 53, and data on the processing results of the company's own waste or consignment of general waste Self-consignment processing result DB 66 and contract work processing result DB 67 for storing data of processing results for contract work Manages the waste inventory DB68 storing data inventory waste after intermediate processing.

  Next, processing contents of the computer system shown in FIG. 1 will be described with reference to FIGS. First, a process in which the person in charge of the intermediate processing facility registers the result of the intermediate processing on a specific day using the intermediate processing facility terminal 3 as preprocessing will be described with reference to FIGS. First, after logging on, the person in charge of the intermediate processing facility causes the intermediate processing facility terminal 3 to access the intermediate processing amount registration page from a predetermined menu screen (step S1). In response to the access from the intermediate processing facility terminal 3 to the intermediate processing amount registration page, the data registration processing unit 52 of the server 5 generates data of the intermediate processing amount registration page and transmits it to the intermediate processing facility terminal 3 (step S2). The intermediate processing facility terminal 3 receives the intermediate processing amount registration page data from the server 5 and displays it on the display device (step S3).

For example, a screen as shown in FIG. 3 is displayed. In the example of FIG. 3, the delete button 301 at the top, the execution button 302 for executing the intermediate processing amount registration, the return button 303 for returning to the previous screen, and the presence of the intermediate processing facility specified from the login information Display column for the name of the shop / power plant to be displayed, a display column for the group to which the person in charge of the intermediate processing facility specified by the login information belongs, a selection column 304 for selecting the intermediate processing facility name, and a processing method are selected. A selection field for selecting a waste name, a selection field 305 for selecting a waste name, a selection field for selecting the type of waste to be intermediately processed, and a processing amount of waste to be intermediately processed (unit: tons) (T)) input field, a processing date selection field 306, a selection field for selecting a waste discharge shop / power plant name, and a selection input field 307 for setting a processing amount input field. included. As described above, in FIG. 3, the data of the entire intermediate process performed on the specific day at the specific intermediate processing facility and the data of the breakdown of the waste processed by the intermediate process are registered. However, it is not directly linked to the waste after intermediate treatment.

  According to the screen as shown in FIG. 3, the user follows the intermediate processing facility name (for example, incinerator), the processing method (for example, incineration), the waste name (for example, wastewater treatment sludge), the waste type (for example, sludge), and the processing amount. (For example, 30), treatment date (for example, July 20, 2003), waste discharge shop / power station (for example, Yokohama Thermal Power Station, Kawasaki Thermal Power Station, Yokosuka Thermal Power Station) and treatment amount (for example 10 , 15, 5) is selected or entered. The intermediate processing facility terminal 3 receives input data from the user (step S5), and transmits the input data to the server 5 in response to the click of the execution button 302 (step S7). The data registration processing unit 52 of the server 5 receives the input data from the intermediate processing facility terminal 3 and stores it in the intermediate processing amount data storage unit 62 (step S9).

  For example, data shown in FIG. 4 is stored in the intermediate processing amount data storage unit 62. In the example of FIG. 4, an intermediate processing facility name column 401, an intermediate processing date column 402, an emission store / power plant column 403, a waste name column 404, and a processing amount column 405 ,. . . And are included. That is, at least one record is generated and registered for each waste discharge store / power plant input on the intermediate processing amount registration page of FIG. The data in the intermediate processing amount data storage unit 62 shown in FIG. 4 is used in a proportional process described later.

  In this way, the data that is the basis of the apportionment process is registered every time the intermediate process is performed, for example.

  Next, the manifest data and its associated information registration processing will be described with reference to FIGS. When issuing or registering the manifest, the person in charge at the site that carries out industrial waste to the outside, after logging in, causes the carry-out site terminal 7 to access the manifest information registration page from a predetermined menu screen (step S11). . The manifest data management unit 51 of the server 5 generates manifest information registration page data in response to the access from the carry-out base terminal 7 and transmits it to the carry-out base terminal 7 (step S13). The carry-out base terminal 7 receives the manifest information registration page data from the server 5 and displays it on the display device (step S15).

  FIG. 6 shows an example (part) of the manifest information registration screen. In the example of FIG. 6, a template registration button 601 for registering the input result as a template, an accompanying information button 602 for transitioning to the accompanying information registration page shown below, and a delete button for deleting this manifest data 603, an issue button 604 for acquiring print data based on the input result, an execution button 605 for executing registration, a return button 606 for returning to the previous screen, a delivery date selection field, Grant number input field, reference number display field, issuer name display field, discharge company name or address and telephone number input field, discharge factory name and address, and telephone number input field Industrial waste selection check box, quantity and unit input / selection column, packing form selection column, industrial waste name selection column, hazardous substance input column, disposal method selection column The remarks communication input column includes a check box for the intermediate processing industrial waste. Although not shown in the drawings, the information input field for the final disposal location, the information input field for the transport consignor, the information input field for the transport site (disposal site), and the information input field for the disposal contractor , Transshipment or storage location name and address entry field, transportation person input field, transportation end date entry field, valuable material collection amount entry field, disposal person input field, final disposal end The input field includes a date input field, a final disposal date input field, an input field of the place where the final disposal was performed, a verification confirmation date input field, and the like.

  The person in charge at the unloading base inputs the manifest data on the input screen as shown in FIG. The manifest data may be input in a plurality of times, but here, for convenience of explanation, it is assumed that all data that can be input at once are input. The carry-out base terminal 7 accepts input of manifest data (step S17). When the person in charge at the unloading base clicks the supplementary information button 602, the unloading base terminal 7 sends the input manifest data and supplementary information registration page / data request to the server 5 in response to the supplementary information registration instruction. (Step S19). When the manifest data management unit 51 of the server 5 receives the manifest data and the incidental information registration page / data request from the carry-out base terminal 7, the manifest data management unit 51 temporarily stores it in, for example, a work memory area (step S21). Then, incidental information registration page data is generated using the received manifest data and transmitted to the carry-out base terminal 7 (step S23). The carry-out base terminal 7 receives the incidental information registration page data from the server 5 and displays it on the display device (step S25).

  FIG. 7 shows an example (part) of the incidental information registration screen. In the example of FIG. 7, as the basic information, the store / power plant included in the manifest data, the reference number, the delivery number, the delivery date, the delivery person, the transportation trustee, the disposal trustee, the final disposal destination, and the waste It includes a name, a waste type, a written quantity (at the time of issuance), and another display field for direct or transshipment, which is the type of manifest person belonging to the person in charge and the type of manifest person. Also, a weight confirmation button 701, a weight confirmation cancellation button 702, a screen clear button 703, an execution button 704 for instructing execution of registration, a return button 705 for returning to the previous screen, and an input of a confirmed weight Column 706, processing category selection column 707, head office supervisory selection column, generation reason selection column, generation reason input column, processing method selection column 708, remarks input column, contract carrier A selection field, a transportation cost selection input field 709, a disposal cost selection input field 710, and various cost selection input fields 711 are included. Furthermore, since the company is carrying out intermediate processing, an intermediate processing facility name selection column 712, an intermediate processing method selection column 713, an intermediate processing waste type selection column 714, and an intermediate processing disposal An item name selection field 715 is provided. In addition, a selection field 716 for effective use in the case of direct internal reuse is also provided. Although not shown in the figure, there are provided a selection field and a free input field for the reason that it cannot be used effectively in the case of in-house landfill, and a selection field and a free input field for the reason that it cannot be used effectively in the case of consignment processing.

  What is input on this supplementary information registration screen is data that is not entered in the manifest, but is required in the apportioning process described later, data required in the aggregation process, and the like.

The person in charge at the carry-out base inputs the incidental information of the manifest on the input screen as shown in FIG. Note that incidental information may be input in a plurality of times, but here, for convenience of explanation, it is assumed that all information that can be input at once is input. The carry-out base terminal 7 accepts incidental information input (step S27). In this case, the person in charge at the unloading base clicks the execution button 704. The carry-out base terminal 7 transmits the input incidental information to the server 5 in response to the execution instruction (step S29). The manifest data management unit 51 of the server 5 receives the incidental information from the carry-out base terminal 7 and temporarily stores it in the work memory area (step S31). And the manifest data management part 51 produces | generates manifest information registration page data again using the manifest data received by step S21, and transmits to the carrying-out base terminal 7 (step S33). The manifest information registration page data is in a form in which the manifest data received in step S21 is input to the input column or selection column. The carry-out base terminal 7 receives the manifest information registration page data from the server 5 and displays it on the display device (step S35). Then, when the person in charge at the unloading base clicks the execution button 605, the unloading base terminal 7 accepts this execution instruction and transmits a manifest registration request including manifest data to the server 5 (step S37). The manifest data management unit 51 of the server 5 receives the manifest registration request including the manifest data from the carry-out base terminal 7, and registers the manifest data together with the accompanying information received in step S31 in the manifest DB 63 (step S39).

  An example of data stored in the manifest DB 63 is shown in FIG. In the example of FIG. 8, the column 801 of the date of issue, the column 802 of the grant number, the column 803 of the reference number, the column 804 of the discharger name, the column 805 of the discharger address, and the name of the discharge business site Column 806, waste type column 807, waste name column 808, final disposal site location column 809, disposal contractor name column 810, processing category column 811, and confirmed weight column 812, processing method column 813, transportation cost column 814, disposal cost column 815, various costs column 820, effective use column 816, company intermediate processing facility name column 817, company Intermediate processing method column 818, pre-intermediate waste name column 819,. . . Is included. The data (not shown) input in FIGS. 6 and 7 is also registered, but is omitted because it is not so relevant in the present embodiment.

  In this way, data to be aggregated in the subsequent aggregation process is registered in the manifest DB 63. In addition, when the intermediate process is performed, the data stored in the manifest DB 63 is also used in the apportioning process described later.

  Next, the process for registering the company-consigned waste results will be described with reference to FIGS. 9 to 11. Manifests are issued only for industrial waste, not for general waste. However, since it is not possible to grasp the processing status of the entire waste without understanding the data on the waste that does not issue a manifest, in this embodiment, the following processing is carried out, so that it is outsourced by the company. Data is registered in the minute processing result DB 66 and is set as a target of the aggregation processing described later. In addition, even if it is a general waste, an intermediate process may be implemented collectively in the specific base in the company, and in that case, it becomes the object of the distribution process demonstrated later.

  First, after logging on, the person in charge at the unloading base or the like causes the unloading base terminal 7 to access the self-consigned waste processing result registration page from a predetermined menu screen (step S41). The data registration processing unit 52 of the server 5 responds to access from the unloading base terminal 7 to the self-consigned waste processing result registration page, generates data of the self-consigned waste processing result registration page, 7 (step S42). The unloading base terminal 7 receives the company-consigned waste processing result registration page data from the server 5 and displays it on the display device (step S43).

  For example, a screen as shown in FIG. 10 is displayed. In the example of FIG. 10, a delete button 1001 at the top, an execute button 1002 for executing registration, a return button 1003 for returning to the previous screen, and a name display field for the store / power plant as the export base Affiliation display column, processing execution date selection column, processing category selection column, waste type selection column, waste name selection column, waste generation amount input column, generation reason selection input column, headquarters supervisory section selection column, Basic information section 1004 including a remarks input field, a collection / transportation company name selection field, a collection / transport contractor company name selection field, a collection / transportation cost input field, an intermediate processing facility name selection field and an intermediate process when intermediate processing is performed In-house processing / disposal unit 1005 including a post-product type selection field, a post-processing weight input field, an effective usage selection field, and an effective usage location selection field, a collection / transportation company name selection field, and a collection / transportation contractor company name selection Column and collection transportation Input field, intermediate processing company name selection field, processing method selection field, intermediate processed product type selection field, post-processing weight input field, effective use application selection field, processing cost input field, and sales cost input field. A consignment processing / disposal part 1006 including a final disposal information part 1007 including a landfill location / company name selection field and a selection input field for an invalid reason for effective use is included.

  In the example of FIG. 10, the basic information is selected or input regardless of whether it is in-house processing / disposal or consignment processing / disposal. In the case of in-house processing / disposal, only the in-house processing / disposal unit 1005 is input. Also in this case, if the intermediate process is performed, data is selected / input in the selection / input field for the intermediate process. When intermediate processing is performed in in-house processing / disposal, it becomes a target of apportionment processing described below, and data input to this in-house processing / disposal unit 1005 is used. In the case of consignment processing / disposal, only the consignment processing / disposal unit 1006 is input. Also in this case, if the intermediate process is performed, data is selected / input in the selection / input field for the intermediate process. However, in this case, the apportioning process is not a target.

  The person in charge at the unloading base inputs or selects data according to the screen as shown in FIG. The carry-out base terminal 7 receives the input data (step S45), and transmits the input data to the server 5 by clicking the execution button 1002 (step S47). The data registration processing unit 52 of the server 5 receives the input data from the carry-out base terminal 7 and stores it in the company commissioned processing result DB 66 (step S49).

  For example, data as shown in FIG. 11 is stored in the self-consignment processing result DB 66. In the example of FIG. 11, a column 1101 of basic information including columns such as a processing execution date, a processing category, a waste type, a waste name, and a waste generation amount, a transportation cost, an intermediate processing facility name, and a post-processing weight. In-house processing / disposal column 1102 including columns such as effective usage and effective usage location, columns of intermediate processing company name, transportation cost, processing method, post-processing weight, effective usage, processing cost, and selling cost A consignment processing / disposal column 1103 including a final disposal information column 1104 including a column such as a landfill company name is included. The data (not shown) input in FIG. 10 is also registered, but is omitted because it is not so relevant in the present embodiment.

  In this way, data that is aggregated in the subsequent aggregation process is registered in the self-consignment processing result DB 66. In addition, when the intermediate process is implemented in the company, the data stored in the company commissioned part processing result DB 66 is also used in the apportioning process described later.

  Next, the processing for registering the actual amount of contract work waste will be described with reference to FIGS. Although waste generated by work originally undertaken by other companies should be handled at the responsibility of the contractor of the work concerned, in this embodiment, in consideration of indirect discharge responsibility, it is subject to aggregation processing. It is what. Therefore, the following processing is basically performed based on information from the contractor. In addition, waste for contract work is not subject to apportionment.

  First, after logging on, the person in charge at the unloading base causes the unloading base terminal 7 to access the waste processing result registration page for the contract work from a predetermined menu screen (step S51). The data registration processing unit 52 of the server 5 generates data of the contracted work waste processing result registration page in response to the access from the export base terminal 7 to the contracted work waste processing result registration page. 7 (step S52). The unloading base terminal 7 receives the contract work waste processing result registration page data from the server 5 and displays it on the display device (step S53).

For example, a screen as shown in FIG. 13 is displayed. In the example of FIG. 13, a delete button 1301 at the top, an execute button 1302 for executing registration, a return button 1303 for returning to the previous screen, a name display field for the store / power plant that is the export base, Affiliation display column, processing execution date selection column, processing category selection column, waste type selection column, waste name input column, waste generation amount input column, prime contractor name selection column, construction subject name input column and occurrence Basic information section 1304 including a reason selection input field, a head office supervisory section selection field, and a remarks input field, a transportation contractor name selection input field, a collection transportation cost input field, a disposal company name selection input field, and a disposal destination Processing / disposal unit 1305 at a contractor including a name selection field, a processing method selection field, an intermediate processing type selection field, and an intermediate processing weight input field in the case of performing intermediate processing, a name of a transportation contractor, etc. Selection input field and collection transportation cost input field and disposal Processing an input column and the effective utilization purpose selecting column weight after intermediate processing after the type of the selected column and the intermediate process when performed with a company name or the like selected input column and disposal destination name selection field processing a physical method selection input field and intermediate processing the final, which includes a processing / disposal unit 1306 in the consignment or the company and an input field of the input field of the cost sale expenses, and landfill destination company name selection field and the disposal site format selection field and effectiveness of unavailability reason selected input field And a disposal information part 1307.

  The person in charge at the unloading base inputs or selects data according to the screen as shown in FIG. The unloading base terminal 7 receives the input data (step S55), and transmits the input data to the server 5 by clicking the execution button 1302 (step S57). The data registration processing unit 52 of the server 5 receives the input data from the carry-out base terminal 7 and stores it in the contract work processing result DB 67 (step S59).

For example, data as shown in FIG. 14 is stored in the contracted work processing result DB 67. In the example of FIG. 14, a basic information column 1401 including columns such as a processing execution date, a processing category, a waste type, a waste name, and a waste generation amount, a transportation cost, a processing method, a weight after intermediate processing, Disposal company processing / disposal column 1402 including the column of the disposal company name, transportation contractor name, collection transportation cost, disposal company name, disposal destination name (our company premises), disposal method, and intermediate post-treatment type and a column 1403 of processing / disposal in the consignment or the company including after the intermediate processing weight and the effective use of applications and processing cost columns such as selling expenses, and a column 1404 of final disposal information, including a string such as landfill destination company name include. Although the data (not shown) input in FIG. 13 is also registered, it is omitted because it is not related in this embodiment.

  In this manner, the data that is the basis of the subsequent aggregation process is registered in the contract work processing performance DB 67.

  Next, when the intermediate process is performed in the company's intermediate processing facility, the apportioning process performed before the aggregation process will be described with reference to FIGS. 15 to 25. The apportioning process is executed at a preset timing such as the end of the month or at an arbitrary timing, for example, when the aggregation process is instructed. Here, the description will be made assuming that the process is executed at a preset timing such as the end of the month. Further, the following processing is performed for each intermediate processing specified by a combination of the intermediate processing facility and the waste name.

  The apportioning processing unit 53 of the server 5 identifies apportioning start data from the apportioning process management table stored in the apportioning process management table storage unit 64 (step S61).

  An example of the apportionment management table is shown in FIG. In the example of FIG. 16, the column 1601 of the intermediate treatment facility, the column 1602 of the waste name, the column 1603 of the previous treatment date, the column 1604 of the previous discharge power plant, the column 1605 of the previous remaining amount, A processing date column 1606, a last discharged power plant column 1607, a final remaining amount column 1608, and a last prorated year / month column 1609 are included. The intermediate processing facility column 1601 identifies which intermediate processing facility is the data. In addition, the waste name column 1602 identifies which waste is the data. In the present embodiment, when the apportionment process is executed at the end of the month, for example, a record for the year is generated when the apportionment process is executed at the end of the month. Therefore, when the apportionment process is performed again for the same year and month later, the apportionment process can be reproduced by referring to the record. The last processing date column 1603, the previous discharge power plant column 1604, and the previous remaining power column 1605 include a last processing date column 1606 and a last discharge power plant column 1607 in the record for the previous month. The value in the final remaining amount column 1608 is registered. A final processing date column 1606, a final emission power plant column 1607, and a final remaining capacity column 1608 indicate the records of the intermediate processing amount data storage unit 62 last specified in the distribution process for a specific month. Data is registered. In the last apportioned year / month column 1609, the date of apportioning processing is registered.

  If the apportioning start data specified in step S61 is the same as the target date of apportionment processing and the value of the last apportionment date column 1609 of any record, the date of previous processing of that record This is the next data after the data in the intermediate processing amount data storage unit 62 specified by the value in the column 1603 and the column 1604 of the previous emission power plant. However, if the value in the last remaining amount column 1605 is other than 0, it is related to the value in the last processing date column 1603 and the data in the intermediate processing amount data storage unit 62 specified in the last discharging power plant column 1604. Thus, the data is divided and generated for the value in the previous remaining amount column 1605. On the other hand, if the target date of the apportioning process is not registered in the last apportioning year / month column 1609 of any record, the last processing date / month column 1606 in the record of the previous month of the apportioning process target month / month, and This is the next data after the data in the intermediate throughput data storage unit 62 identified in the column 1607 of the final emission power plant. However, if the value in the final remaining amount column 1608 is other than 0, in relation to the data in the intermediate throughput data storage unit 62 specified in the final processing date column 1606 and the final discharge power plant column 1607, This is data generated by division for the value in the final remaining amount column 1608.

  If NULL is registered in the last prorated year / month column 1609 as shown in FIG. 16A, processing is performed from the first record in the intermediate throughput data storage unit 62. Further, when the apportionment start data is specified from the last processing date column 1603 or the like, and NULL is registered in the last processing date column 1603 or the like, the intermediate processing amount data storage unit 62 is also provided. Process from the first record of. Note that for the first record, if data that fits to some extent is not specified, there will be a discrepancy in later proportional processing. Here, the intermediate processing facility will be described as starting from the first record. However, appropriate data may be determined as the distribution start data using the distribution start data automatic determination processing unit 531 described later.

  Next, unprocessed records related to intermediate processing by the company's intermediate processing facility are extracted from the manifest DB 63 and the company's commissioned processing result DB 66, and stored in, for example, a work memory area (step S63). For unprocessed records, processing / unprocessed data may be registered in the manifest DB 63 and the self-consigned processing result DB 66, or information for identifying the prorated processing may be registered in the intermediate processing tabulation DB 65. Or you may make it specify from it. Hereinafter, a record registered in the manifest DB 63 will be described as an example.

An example of data stored in the work memory area is shown in FIG. In the example of FIG. 17, from the serial number column 1700 in which data extracted from the serial number column 803 of the manifest DB 63 (FIG. 8) is stored, and from the delivery date 801 of the manifest DB 63 (FIG. 8). a column 1701 of the disposal date of data to be extracted is stored, a manifest DB 63 column 1702 waste name data is stored to be extracted from column 808 waste name (FIG. 8), the manifest Data extracted from the column 1703 of the intermediate processing facility in which data extracted from the column 817 of the company's intermediate processing facility name in the DB 63 (FIG. 8) is stored, and the column 812 of the confirmed weight in the manifest DB 63 (FIG. 8) And a column 1704 of the determined weight in which is stored. Only relevant data is shown here. Here, it is assumed that an unprocessed record about sludge ash generated when sludge is incinerated in the A incinerator is extracted.

  Next, one record among the records extracted in step S63 is specified as a processing target (step S65). Then, the weight reduction coefficient corresponding to the waste name for the record to be processed is read from the various parameter storage units 61, and the quantity before intermediate processing is calculated from the determined weight value of the record to be processed using the weight reduction coefficient. Is calculated and stored in, for example, a work memory area (step S67). For example, if the sludge ash reduction coefficient is 0.2, the determined weight is 8 (t), so the weight before intermediate treatment is 40 (t).

  Then, the apportioning processing unit 53 obtains the intermediate processing amount data corresponding to the intermediate processing facility specified from the processing target record and the waste name before the intermediate processing from the intermediate processing amount data storage unit 62 and after the apportioning start data. Extracted and read out to, for example, a work memory area (step S69). For example, data as shown in FIG. 4 is extracted.

  Further, the apportioning processing unit 53 accumulates the processing amount for the intermediate processing amount data after the apportioning start data, and specifies the intermediate processing amount data that is the quantity before the intermediate processing calculated in step S67 (step S71). When processing the first record in FIG. 17, the state of accumulating the values in the processing amount column 405 in FIG. 4 in order from the top is schematically shown in FIG. 18. As shown in the accumulated (t) column 1801 in FIG. 18, when the processing amount of the first data to the seventh data is accumulated, the amount 40 (t) before the intermediate processing calculated in step S67 is reached. Therefore, the data specified in step S71 is the seventh data 1802. However, although the processing amount of the seventh data is 12 (t) as a whole, the amount before the intermediate processing has reached 40 (t) only by 2 (t). Accordingly, the seventh data is divided into data 1802 with a processing amount of 2 (t) and data 1803 with a processing amount of 10 (t) as the remaining amount. This data 1803 is used in later processing.

  Thereafter, the processing amount is totaled for each emission power plant, the weight after the intermediate processing is calculated based on the weight reduction coefficient stored in the various parameter storage unit 61 and used in step S67, and stored in the work memory area, for example. (Step S73). For example, data as shown in FIG. 19 is generated. In the example of FIG. 19, a reference number column 1900, a generated power plant column 1901, a disposal date column 1902, a waste name column 1903, a generated amount column 1904, and a post-treatment weight column. 1905, a transportation cost column 1906, a disposal cost column 1907, and various cost columns 1908 are provided. In this step S73, for the generated power plant A, the processing amount of the first data, the second data, the fourth data, the sixth data, and the seventh data in FIG. In addition, the post-intermediate weight is calculated according to the weight reduction coefficient 0.2, and the value 5.8 is registered in the post-process weight column 1905. Similarly, for the power plant B, a value of 6 is registered in the generated amount column 1904 from the processing amount of the fifth data in FIG. 18, and the weight after the intermediate processing is calculated according to the reduction coefficient 0.2. A value of 2 is registered in the processed weight column 1905. Further, for the power plant C, a value of 5 is registered in the generated data column 1904 from the processing amount of the third data in FIG. Is registered in the processed weight column 1905. It should be noted that, instead of a reduction coefficient, for example, a distribution coefficient that is a ratio of the generation amount of each power plant (discharge base) to the total generation amount is calculated, and each power generation is obtained by multiplying the distribution coefficient by the determined weight shown in FIG. The post-processing weight of the place (discharge base) may be calculated. For example, the distribution coefficient of the power plant A is 29/40 = 0.725, and is calculated as a determined weight 8 × a distribution coefficient 0.725 = 5.8.

  Then, the apportionment processing unit 53 refers to the various parameter storage units 61, reads out the unit price of the transport cost of the waste after the intermediate processing, the unit price of the disposal cost, and the unit price of the various costs, and each power plant (discharge The transportation cost, disposal cost, various expenses, etc. of the base) are calculated and registered in the table (FIG. 19) provided in the work memory area (step S75). In the example shown in FIG. 19, the unit cost of transportation costs is 60,000 yen / t, the unit cost of disposal costs is 50,000 yen / t, and the unit price of various expenses is 30000 yen / t. The data generated in this way (FIG. 19) is registered in the intermediate process totalization DB 65 (step S77).

  Then, it is determined whether all the records extracted in step S63 have been processed (step S79). If there is an unprocessed record, the distribution start data is set to the next data of the intermediate processing amount data specified in step S71 for the processing of the next record (step S81). When the remaining amount is generated, the data is divided and generated. Then, the process returns to step S65.

  On the other hand, if there is no unprocessed record, the last process date is displayed in the last process date column 1603, the last discharged power plant column 1604, and the last remaining capacity column 1605 as a new record in the apportionment process management table. The values stored in the day column 1606, the last emission power plant column 1607, and the last remaining power column 1608 are registered, and the last processing date column 1606, the last discharged power plant column 1607, and the final remaining power amount are registered. In column 1608, the intermediate processing date of the intermediate processing amount data specified in step S71, the discharged power plant, and the remaining amount of the record are registered (step S83). In the last proration date column 1609, the current date is registered. Note that this step is skipped when the apportionment process is performed again for the same date.

  For example, when the processing is started in the state of FIG. 16A and the intermediate processing amount data of the A power plant on April 28, 2003 is specified and the remaining amount is 2, the processing shown in FIG. Such data is registered in step S83. That is, the value (NULL) of the last processing date column 1606 in FIG. 16A is registered in the last processing date column 1603 in FIG. 16B, and the previous emission power generation in FIG. The value (NULL) of the last emission power plant column 1607 of FIG. 16A is registered in the column 1604 of FIG. 16A, and the last remaining amount of FIG. 16A is registered in the last remaining amount column 1605 of FIG. The value (0) in the column of the quantity column 1608 is registered. In addition, 03/4/28 is registered in the column 1606 of the final processing date in FIG. 16B, and A is registered in the column 1607 of the final emission power plant in FIG. 16B. 2 is registered in the last remaining amount column 1608 of b), and 2003304 meaning April 2003 is registered in the last prorated year / month column 1609. If the apportionment process for May 2003 is performed, data as shown in FIG. 16C is registered in accordance with the contents described in step S83.

As a precaution, the processing when the second record in FIG. 17 is processed will be described. In the second record, the determined weight is 4 (t), and the quantity before processing is calculated as 20 from the reduction rate. Then, the intermediate processing amount data that becomes 20 by accumulating the intermediate processing amount in order from the data (intermediate processing amount 10) divided and generated from the seventh data of FIG. 4 is specified. This is shown in FIG. In Figure 20, the intermediate processing amount of data divided generated from the seventh data of FIG. 4, the intermediate treatment of the eighth data, intermediate processing amount when accumulating the intermediate processing of the ninth data Ding of 20 ( t). When the data shown in FIG. 20 is totaled at the discharge power plant (discharge base), data as shown in FIG. 21 is obtained. As shown in FIG. 21, the intermediate processing amount is 10 for power plant A, and the intermediate processing amount is 10 for power plant C. Therefore, the distribution coefficient is 0.5 for both the power plant A and the power plant C, and the weight after treatment is two. Thereafter, the transportation cost, the disposal cost, and the various expenses are calculated according to the unit price of the transportation cost, the unit price of the disposal cost, and the unit price of the various expenses stored in the various parameter storage units 61. In addition, since there is no intermediate processing amount for the power plant B, no waste is distributed. The data shown in FIG. 21 is registered in the intermediate processing totalization DB 65.

  In this way, even when intermediate processing is carried out in-house, waste after intermediate processing can be appropriately allocated to the site that discharged the waste before intermediate processing. There will be no rational apportioning.

  In addition, when the intermediate processing amount in the intermediate processing amount data is accumulated in order according to the date in step S71, the intermediate processing amount data including the intermediate processing amount that exceeds the intermediate processing amount converted from the determined weight by the reduction coefficient. Is present in the intermediate throughput data storage unit 62, there is no problem, but in some cases, the intermediate throughput data may be insufficient. For example, consider the case of processing for a record as shown in FIG. Since the final weight is 8, the quantity before intermediate processing is 40 when the weight reduction rate is 0.2. On the other hand, as described above, when the intermediate processing amounts in the intermediate processing amount data are accumulated in order of date from the distribution start data, as shown in FIG. 22B, FIG. Even if the intermediate processing amount is accumulated beyond the disposal date (03/04/30) of the indicated processing target record, there may be a situation where the quantity before the intermediate processing converted from the confirmed weight is not reached. . In this case, it is only 35 (t), so there is clearly a shortage. In such a case, the intermediate processing amount is accumulated retroactively from the last data before the disposal date of the processing target record shown in FIG. This situation is shown in FIG. In the record to be processed shown in FIG. 22A, the disposal date is April 30, 2003, and in FIG. 22B, the last data before the disposal date is April 28, 2003. It is the data of the power plant B, and it is accumulated from the intermediate processing amount of this data. If it does so, it will reach the quantity 40 before the intermediate | middle process converted from the fixed weight by the 5th data from the back. Therefore, when the data is tabulated for each discharged power plant, the state shown in FIG. 23B is obtained. The generated amount (intermediate processing amount) of the power plant A is 15, and the weight after the intermediate processing is 3. The generated amount (intermediate processing amount) of the power plant B is 9, and the weight after the intermediate processing is 1.8. The generation amount (intermediate processing amount) of the power plant C is 16, and the weight after the intermediate processing is 3.2. If it can be calculated in this way, the cost can also be calculated. In such exceptional processing, an error is generated in some apportionment. However, since the apportionment is more accurate than the calculation according to the conventional technique, this numerical value is adopted.

In the above example, the apportioning start data is specified from the apportioning process management table. However, there is a problem of which data should be used as the apportioning start data in the very first process. If apportionment start data is not properly specified, an error will occur in apportionment. If possible, it may be set to the first data on the day when the intermediate processing facility is operated. However, in this case, it can be set only for a new intermediate processing facility. However, if there is accumulation of data for a certain period, the distribution start data can be automatically specified. Therefore, the apportioning start data automatic determination processing unit 531 refers to the stock amount of the waste after the intermediate processing stored in the waste stock DB 68, and the stock amount of the waste after the intermediate processing becomes zero. The day is searched and if it can be specified, the data for that day is specified as the distribution start data. For example, data as shown in FIG. 24 is stored in the waste inventory DB 68. In the example of FIG. 24, a column 2400 of a date, a store name column 2401 that stores waste, a storage location name column 2402, a waste name column 2403, and a quantity column 2404 , A unit column 2405 and an affiliated group column 2406 are provided. In this way, data indicating what kind of waste is stored for each date and storage location is stored. Therefore, the waste inventory DB 68 is searched for the date when the quantity column 2404 becomes 0 for the waste to be processed.

  However, in general, there are not many days when the stock amount becomes 0, so next, the stock amount of waste before intermediate processing is stored in various parameter storage units 61 from the current stock amount of waste after intermediate processing. It is calculated using the weight reduction rate that is stored, and stored in the work memory area. Here, it is assumed that the stock amount of waste before intermediate processing is 150 (t). Then, the intermediate processing amount stored in the waste data before the intermediate processing stored in the intermediate processing amount data storage unit 62 is accumulated retroactively starting from the last data of the current date. This example is shown in FIG. Since there is no data on the current date (April 1), if the intermediate processing amount is accumulated retroactively from March 31, the data for March 21 will be 150 (t). Therefore, if the data of March 21 is set as the apportioning start data, no fraction occurs in the subsequent processing, and the apportioning process proceeds smoothly.

  Next, a process in the case of approving the monthly waste process or referring to the result of the monthly waste process will be described with reference to FIGS. For example, a person who refers to the monthly count result causes the in-house terminal 9 to send a request for a monthly waste processing result count result confirmation page from a predetermined menu screen after the login process (step S91). The aggregation processing unit 55 of the server 5 receives the request for the monthly waste result aggregation result confirmation page from the in-house terminal 9 (step S93), and for example, the aggregation target store and the current year from the login ID. Is specified (step S95). Note that these may be designated by the user of the in-house terminal 9. Then, the data for the consignment processing of the general waste is extracted from the data registered in the company consignment processing result DB 66 in accordance with the store and the date specified in step S95, and the aggregation processing is performed (step S97). . In this tabulation process, if the data other than the numeric value is the same among the extracted data, the numeric data is tabulated as the same type of data and stored in, for example, a work memory area.

  Moreover, the totalization process part 55 implements the total for the in-house processing of general waste (step S99). This process will be described with reference to FIG. The aggregation processing unit 55 searches the in-house commissioned processing result DB 66 according to the store and year specified in step S95, and stores the corresponding records for in-house processing in, for example, the work memory area (step S121). Then, records corresponding to the intermediate processing performed at the store specified in step S95 are extracted and removed from the records stored in the work memory area (step S123). As for the record indicating that the intermediate processing has been performed, if the tabulation processing is performed based on the data extracted from the self-consignment processing result DB 66, all of the records are discharged, resulting in excessive tabulation. Therefore, step S123 is performed. In the example of FIG. 11, whether or not intermediate processing is being performed is determined by whether or not the intermediate processing facility of this store is registered in the column of intermediate facility name in the in-house processing / disposal column 1102. .

  Then, the totalization processing unit 55 searches the intermediate processing totalization DB 65 by the store and year specified in step S95, and extracts records corresponding to the store and year and month and related to general waste (step). S125). The extraction result is read out to a work memory area, for example. Whether it is general waste or not is specified from the waste name. Then, records that are read into the work memory area and that match data other than numerical values are aggregated, and the aggregation result is stored in the work memory area (step S127). The data for the intermediate processing performed by the company is also aggregated using the data of the corresponding records in the company commissioned processing result DB 66. Then, the process returns to the process of FIG.

  Next, the tally processing unit 55 performs a tally process for the manifest (step S101). This process will be described with reference to FIG. The tabulation processing unit 55 searches the manifest DB 63 according to the store location and year specified in step S95, and stores the corresponding record in, for example, a work memory area (step S131). Then, records corresponding to the intermediate processing performed at the store specified in step S95 are extracted and removed from the records stored in the work memory area (step S133). As for the record indicating that the intermediate processing has been performed, if the aggregation processing is performed based on the data extracted from the manifest DB 63, all is discharged from the store, and thus excessive aggregation is performed. Step S133 is performed. Whether or not intermediate processing is being performed is determined by whether or not the intermediate processing facility of this store is registered in the company's intermediate processing facility name 817 in the example of FIG.

  Then, the totalization processing unit 55 searches the intermediate processing totalization DB 65 for the store and year specified in step S95, and finds a record corresponding to the store and year and month and related to the manifest (ie, industrial waste). Extract (step S135). The extraction result is read out to a work memory area, for example. Whether or not it is a manifest issue is specified from the waste name. Then, records that are read into the work memory area and that match data other than numerical values are aggregated, and the aggregation result is stored in the work memory area (step S137). Note that data corresponding to the intermediate processing is aggregated using corresponding records in the manifest DB 63. Then, the process returns to the process of FIG.

  After performing the processing as described above, the aggregation processing unit 55 generates page data including the data of the aggregation results held in the work memory area, and transmits it to the in-house terminal 9 (step S103). The in-house terminal 9 receives the page data including each count result from the server 5 and displays it on the display device (step S105).

For example, a screen as shown in FIG. 29 is displayed. In the example of FIG. 29, a monthly result totaling instruction screen display button 2901, an approval screen display button 2902, an execution button 2903 for executing a totaling process based on the setting of basic information described below, and the previous screen are returned. A return button 2904, a store selection field 2905, a target year / month selection field 2906, another selection field 2907 for own company or contract, and a waste processing result list display field 2908 are included. The waste results list includes industrial waste classification, treatment classification, waste type, waste name, generation amount, collection and transportation cost, disposal cost, various expenses, usage destination, usage, sale price, in-house (intermediate) There are columns for the company's post-processing amount, other company's intermediate processing (processing company name), other company's processing method, other company's intermediate processing, final disposal (disposal destination), disposal method, and final landfill amount .

For example, in the case of data from the manifest DB 63, the value of the waste type column 807 in FIG. 8 is displayed in the industrial waste column, and the value of the processing column 811 in FIG. In the type column, the value in the waste type column 807 in FIG. 8 is displayed. In the waste name column, the value in the waste name column 808 in FIG. 8 is displayed. The aggregated value in column 812 is the aggregated value in column 814 for transportation costs in FIG. 8 for the column for collection and transportation costs, and the aggregated value in column 815 for disposal costs in FIG. 8 shows the total value in the column 820 of various expenses in FIG. 8, the value in the column 809 of the location of the final disposal site in the (effective) usage destination column, and the effective usage in FIG. 8 in the column of (useful) usage The value in the use column 816 is the value of the column 818 of the company's intermediate processing method in FIG. 8 for the column of the company's intermediate process, and the value of FIG. The total value in the column 812 of the confirmed weight is the value in the column 810 of the disposal contractor name in FIG. 8 in the column of the other company's intermediate process (processing company name), and the process in FIG. The value of the column 813 of the method is the value of the column 809 of the location of the final disposal site in FIG. 8 in the column of the final disposal (disposal destination), and the value of the column 813 of the processing method in FIG. In the final landfill amount column, the total values in the determined weight column 812 of FIG. 8 are used. In addition, when the intermediate process is implemented in-house, the numerical value stored in the corresponding intermediate process totalization DB 65 is used.

For example, in the case of data from the self-consignment processing result DB 66, the value of the waste type column in the basic information column 1101 of FIG. 11 is displayed in the industrial waste column, and the basic information of FIG. The column of the processing classification in the column 1101, the waste type column, the waste type column value in the basic information column 1101 in FIG. 11, the waste name column in the basic information column of FIG. The waste name column value in the column 1101, the generated value column is the aggregate value of the waste generated amount column in the basic information column 1101 in FIG. 11, and the collection and transportation cost column is in-house in FIG. The total value of the transportation cost column in the processing / disposal column 1102 or the total value of the transportation cost column in the consignment processing / disposal column 1103 is the processing value in the consignment processing / disposal column 1103 in FIG. The aggregate value in the cost column is (effective) interest In the previous column, the value of the column of the effective usage place in the column 1102 for in-house processing / disposal in FIG. 11 or the value of the column of the intermediate processing company in the column 1103 of the consignment processing / disposal is the column of (effective) usage purpose. 11 shows the value of the column for effective use in the in-house processing / disposal column 1102 of FIG. 11 or the value of the column for effective usage in the column 1103 of consignment processing / disposal, and the consignment processing of FIG. / Disposal column 1103 shows the value of the sale cost column, and in-house intermediate processing column shows the value of the in-house processing / disposal column 1102 in FIG. 11 shows the value of the post-processing weight column in the in-house processing / disposal column 1102 in FIG. 11, and the other company's intermediate processing (processing company name) column shows the intermediate processing in the consignment processing / disposal column 1103 in FIG. The value in the company name column is 11 shows the value of the column of the processing method in the consignment processing / disposal column 1103 of FIG. 11, and the column of the final disposal (disposal destination) shows the value of the landfill company in the column 1104 of the final disposal site information of FIG. The name column value is the disposal method column, the final disposal information column column 1104 in FIG. 11 is the landfill site name column value, and the final landfill column is the in-house processing / disposal column in FIG. The value of the post-processing weight column in 1102 or the value of the post-processing weight column in the commissioning / disposal column 1103 is used. In addition, when the intermediate process is implemented in-house, the numerical value stored in the corresponding intermediate process totalization DB 65 is used.

  In this way, the user can use the contents of the screen as shown in FIG. 29 displayed on the display device of the in-house terminal 9 to store a specific store that is stored in the manifest DB 63, the intermediate processing totalization DB 65, and the company commissioned processing performance DB 66. In addition, it becomes possible to collect and collect waste data on the year and month. In addition, even if the company implements intermediate treatment, it is possible to aggregate and display the results of the accurate proportional treatment as described above, so that the actual state of waste treatment can be grasped more appropriately. become. In addition, you may instruct | indicate so that a store location and a date may be changed and displayed at this time. In that case, the process returns to step S95.

  Next, for example, when the user designates the contract work in the company / contract category selection field 2907 in FIG. 29 and clicks the execution button 2903, the in-house terminal 9 receives the contract work display instruction and displays the contract work display. An instruction is transmitted to the server 5 (step S107). The tabulation processing unit 55 of the server 5 receives the contract work display instruction from the in-house terminal 9, and executes the tabulation processing for the contract work accordingly (step S109). This process searches the contract work processing result DB 67 by the store and year specified in step S95, extracts corresponding records, and aggregates records that match data other than numerical values, and performs aggregation processing. Store the result in the work memory area. Then, the aggregation result confirmation page data for the contract work is generated using the aggregation processing result and transmitted to the in-house terminal 9 (step S111). The in-house terminal 9 receives the summary result confirmation page data for the contract work from the server 5, and displays it on the display device (step S113).

  The configuration of the screen displayed in this scene is almost the same as that shown in FIG. 29, but the content is waste data for contract work.

Note that the value of the waste type column in the basic information column 1401 in FIG. 14 is displayed in the industrial waste column, and the value of the processing column in the basic information column 1401 in FIG. The value of the waste type column in the basic information column 1401 of FIG. 14 is generated in the item type column, and the value of the waste name column in the basic information column 1401 of FIG. 14 is generated in the waste name column. In the column of quantity, the total value of the column of waste generation in the basic information column 1401 in FIG. 14 is shown, and in the column of collection and transportation cost, the column of transportation cost in the processing / disposal column 1402 of the contracting company in FIG. 14 or the collection / transportation cost column in the column 1403 of consignment or processing / disposal in our company, and the disposal cost column shows the processing cost in the column 1403 of consignment or processing / disposal in our company The aggregate value of the column is (valid) in the column of the usage destination. The value of the column of the disposal company name or the value of the column of the disposal destination name (our premises) in the column 1403 of the consignment or processing / disposal in our company, and the (useful) usage column are the consignment or our company in FIG. In the column 1403 for effective use in the processing / disposal column in FIG. 14, the column for effective use is in the column for sale amount, and the aggregate value in the column for selling expenses in the column 1403 for consignment or processing / disposal at our company is In the processing column, the value of the processing method column in the processing / disposal column 1402 at the contracting company in FIG. 14 or the value of the processing method column in the processing / disposal column 1403 at the consignment or our company is the In the column of post-processing amount, the value of the intermediate post-processing weight column in the processing / disposal column 1402 of the contractor in FIG. 14 or the value of the intermediate post-processing weight column in the processing / disposal column 1403 of consignment or our company is shown. Of the other company's intermediate processing (processing company name) 14 shows the value of the column of the disposal company name in the processing / disposal column 1402 or the value of the disposal company name column in the processing / disposal column 1403 of the consignment or our company in FIG. In the column of the processing method of FIG. 14, the value of the column of the post-intermediate weight in the column of the processing / disposal column of the contractor in FIG. , the value of the column of landfill partner company name in column 1404 of the final disposal site information in column 14 of the final disposal (disposal destination) is the column of disposal of processing / disposal at contractors in FIG 14 column The processing method column value in 1402 or the processing method column value in the consignment or our processing / disposal column 1403 is the final landfill amount column in the processing / disposal column 1402 in the contracting company in FIG. Intermediate post-processing column value or consignment or processing at our company The values in the post-intermediate weight column in the / disposal column 1403 are used respectively.

  Although the embodiment according to the present invention has been described above, the present invention is not limited to this. For example, although some screen configuration examples are shown, the present invention is not limited to such a screen configuration, and other screen configurations including other similar contents may be adopted. In addition, regarding the registration processing flow of various data, data may be registered according to another processing flow.

  In the above, the weight after the intermediate treatment is converted to the weight before the intermediate treatment, but the weight before the intermediate treatment is converted into the weight after the intermediate treatment. May be.

  Furthermore, the functional block diagram shown in FIG. 1 is an example of the system configuration and is not necessarily limited to this system configuration. Further, each processing unit included in the server 5 does not necessarily correspond to a program module. Also, the various data storage units and DBs do not have to be divided in the above-described manner, and the areas may be stored separately in one or a plurality of storage devices.

  In the above description, the example in which the distribution process is performed at a timing different from the aggregation process is shown, but the distribution process may be included in the flow of FIG. Further, since the data is stored in the intermediate process totalization DB 65, the apportionment process may be performed not only at a preset timing such as the end of the month but at an arbitrary timing. At this time, the data of the apportioning process management table need only hold the data in the intermediate processing amount data storage unit 62 specified last in the specific apportioning process.

It is a system outline figure concerning one embodiment of the present invention. It is a figure which shows the processing flow for registering the data of the intermediate processing amount processed in the intermediate processing facility. It is a figure which shows an example of an intermediate processing amount registration screen. It is a figure which shows an example of the data stored in an intermediate processing amount data storage part. It is a figure which shows the processing flow for registering manifest data. It is a figure which shows an example of a manifest information registration screen. It is a figure which shows an example of a manifest incidental information registration screen. It is a figure which shows an example of the data stored in manifest DB. It is a figure which shows the processing flow for a company commissioned waste track record registration. It is a figure which shows an example of a company commissioned waste results registration screen. It is a figure which shows an example of the data stored in a company commissioned part process performance registration DB. It is a figure which shows the processing flow for the waste processing result registration for contract work. It is a figure which shows an example of the contract work waste processing result registration screen. It is a figure which shows an example of the data stored in contract work part processing performance DB. It is a figure which shows the processing flow of the apportionment process. (A) thru | or (c) is a figure which shows the example of data of the apportionment process management table. It is a figure which shows an example of the data of manifest DB extracted in the distribution process. It is a figure which shows an example of the data of the intermediate | middle processing amount data storage part extracted in the distribution process. It is a figure which shows an example of the data stored in intermediate process totalization DB. It is a figure which shows an example of the data of the intermediate | middle processing amount data storage part extracted in the distribution process. It is a figure which shows an example of the data stored in intermediate process totalization DB. (A) is a figure which shows an example of the data of the manifest DB extracted in the distribution process, (b) is a figure which shows an example of the data of the intermediate processing amount data storage part extracted in the distribution process. is there. (A) is a figure which shows an example of the data of the intermediate process amount data storage part extracted in the apportionment process, (b) is a figure which shows an example of the data stored in intermediate process totalization DB. It is a figure which shows an example of the data stored in waste inventory DB. It is a figure for demonstrating the automatic determination process of the distribution start date. It is a figure which shows the processing flow for a monthly waste processing performance total result confirmation. It is a figure which shows the processing flow of the total process for the company's internal waste processing. It is a figure which shows the processing flow of the total process for a manifest. It is a figure which shows an example of a monthly waste processing performance total result confirmation screen. It is a figure for demonstrating a prior art.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Network 3 Intermediate processing facility terminal 5 Server 7 Carry-out base terminal 9 In-house terminal 51 Manifest data management part 52 Data registration processing part 53 Apportionment processing part 55 Aggregation processing part 531 Apportionment start data automatic determination processing part 61 Various parameter storage part 62 Intermediate processing Quantity data storage unit 63 Manifest DB 64 Apportioning processing management table storage unit 65 Intermediate processing totaling DB 66 Self-consigned processing result DB
67 Subcontracting work results DB 68 Waste inventory DB

Claims (10)

An information processing method related to intermediate processing of waste in a company having a plurality of discharge bases,
A first data storage in which a computer stores waste weight data , discharge site data, and data indicating whether or not intermediate processing has been performed, and stores a record relating to the waste. By searching for data based on data indicating whether or not the intermediate processing has been performed, and extracting a distribution basic record that includes the waste weight data and is a record for the waste that has been subjected to the intermediate processing And a distribution basic record extraction step for storing in the storage device;
The computer converts the waste weight in the allocation basic record into a waste weight before intermediate processing, and generates converted waste weight data;
Second that the computer stores a record including an intermediate processed waste to intermediate treatment before the waste weight data and intermediate processing date waste discharged from the data and the discharge site of the discharge base data In the data storage unit, for the records that have not been prorated, the waste weights before the intermediate processing included in the records are accumulated in ascending order of the dates of the intermediate processing, and the cumulative result reaches the post-conversion waste weights. An intermediate processing record extraction step that identifies the record group up to the intermediate processing record and stores it in the storage device;
The computer aggregates the waste weight before the intermediate processing included in the intermediate processing record stored in the storage device for each of the discharge bases included in the intermediate processing record, and calculates the base waste weight as the discharge base. Calculating for each of the discharge bases a distribution coefficient that is a ratio of the base waste weight to the total waste weight before the intermediate processing included in the intermediate processing record. A distribution step of allocating a material weight to each of the discharge bases according to the distribution coefficient and storing the distribution result in a distribution result storage unit;
Including information processing methods. The intermediate processing record extraction step includes:
When accumulating the waste weight before the intermediate treatment, if there is no record that can be used before the converted waste weight is reached, the waste weight before the intermediate treatment is traced back in order from the last record. an information processing method including according to claim 1, wherein the step of identifying a group of records until the record reaches the waste weight after the conversion as the intermediate processing record by accumulating. The intermediate processing record extraction step includes:
When the cumulative result of accumulating the waste weight before the intermediate processing included in the record of the second data storage unit exceeds the converted waste weight in the record reaching the converted waste weight, the excess amount wherein generating a record for the waste weight before the intermediate treatment, information processing method including according to claim 1 or 2, wherein the step of storing in the storage device. When performing the intermediate process record extraction step for the first time, the intermediate process record extraction step,
Go back in order from the date when the waste stock amount after the intermediate treatment becomes 0 in the database for managing the waste stock amount after the intermediate treatment every day , or from the last record stored in the second data storage unit The cumulative result of accumulating the weight of the waste before the intermediate processing included in the record of the second data storage unit is obtained from the database, and the waste inventory on the day when the intermediate processing record extraction step is executed for the first time A record in the second data storage unit for a date that reaches the waste weight before intermediate processing converted from the quantity is specified as a first intermediate processing record, and the second intermediate data is recorded in ascending order of date from the first intermediate processing record. Accumulating the waste weight before the intermediate processing included in the record of the data storage unit, and the cumulative result from the first intermediate processing record is the converted waste weight An information processing method to record group to record identified as intermediate processing records, any one described steps including claims 1 to 3 to be stored in the storage device to reach. The computer calculates a cost for waste processing based on the waste weight data of each discharge base stored in the distribution result storage unit, and stores the expense in the distribution result storage unit;
The information processing method according to any one of claims 1 to 4 , further comprising: The data stored in the first data storage unit is at least one of manifest data for processing industrial waste, data related to the manifest, and data for general waste processing. any one information processing method according to claim 1, wherein. The record of the first data storage unit further includes waste type data;
The record of the second data storage unit further includes waste type data;
The intermediate processing record extraction step and the apportioning step are performed for each type of waste,
When data collection is instructed for a specific emission site,
The computer is a record relating to the specific discharge base and the intermediate process is performed based on the data of the discharge base and the data indicating whether or not the intermediate process has been performed from the first data storage unit. extracting non records, a step by aggregating records the extracted for each type of the waste, which generates a first aggregate data, stored in the storage device,
The computer extracts data relating to the specific discharge base from the distribution result storage unit , and generates second aggregated data by aggregating the extracted records for each type of waste , Storing in a storage device;
The computer outputting the first and second aggregated data stored in the storage device;
The information processing method according to any one of claims 1 to 6 , further comprising: When data collection is instructed for a specific emission site,
The computer, from the third data storage unit that stores records for data and and the waste include the type of data waste discharge locations of waste discharged by contract work by others has undertaken, of the discharge base the extracts records for a particular discharge sites on the basis of the data, to generate a third aggregate data by aggregating records the extracted for each type of the waste based on the type of data of the waste, Storing in the storage device;
The computer outputting the third aggregated data stored in the storage device;
The information processing method according to claim 7 , further comprising: A program for causing a computer to execute the information processing method according to any one of claims 1 to 8 . A computer system for performing information processing related to intermediate processing of waste in a company having a plurality of discharge bases,
A first data storage unit that includes waste weight data , waste base data, and data indicating whether or not intermediate processing has been performed, and stores a record relating to the waste ; By searching based on data indicating whether or not the intermediate processing has been performed, an allocation basic record that includes the waste weight data and is a record for the waste that has been subjected to the intermediate processing is extracted and stored. Means for storing in the device;
Means for converting the waste weight in the distribution basic record into a waste weight before intermediate treatment, and generating data of the converted waste weight;
In the second data storage unit that stores a record including the intermediate processed waste to intermediate treatment before the waste weight data and intermediate processing date waste discharged from the data and the discharge site of the discharge base data , A record group in which the weight of waste before the intermediate processing included in the record is accumulated in ascending order of the date of intermediate processing for records that have not been prorated, and the cumulative result reaches the waste weight after conversion As an intermediate processing record and stored in a storage device;
Summarizing the waste weight before the intermediate processing included in the intermediate processing record stored in the storage device for each of the discharge bases included in the intermediate processing record to determine the base waste weight for each of the discharge bases, said proportional division factor is the ratio of the base waste weight to the total waste weight before the intermediate treatment in the intermediate processing records to calculate for each of the discharge base, the said waste by weight contained in the allocation basic record Means for allocating to each of the discharge bases according to a proration coefficient and storing the distribution result in a distribution result storage unit;
A computer system.

Images