JP2010238084A - Production information management system and method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a production information management system and method, allowing flexible display of data of a managed productivity-reliability evaluation index by a method by which the display is desired by only setting. <P>SOLUTION: A data collection-totaling function block 120 stores data performed with collection processing by a function block 122 executing the data collection processing into an RDB (relational database) 124, and creates various general-purpose Views (including a general-purpose View file) by use of information stored in the RDB 124. In an engineering function block 180, generation processing of an XML structure file 184 is performed by engineering tool processing 182. A screen display system 200 includes a screen display function block 210. The screen display function block 210 includes a function of performing display execution of various graphs each presenting the productivity-reliability evaluation index in a production system on a screen of an information management device 10 based on the setting of a user. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a production information management system and method, and more particularly to a production information management system and method for managing information that is an evaluation index of productivity and reliability in a production system such as a key performance indicator (KPI).

  Patent Document 1 below discloses a means for calculating a time operating rate, a means for calculating a performance operating rate, a means for calculating a non-defective product rate, and a unit for calculating a product of the time operating rate, the performance operating rate, and the non-defective product rate. , And provides an index that can evaluate the production efficiency of each of a plurality of equipments at the processing site in the same row, and discloses an overall equipment effectiveness (OEE) calculation device that calculates the index.

  In addition, Patent Document 2 below automatically collects the operating status of a plurality of currently operating facilities, and predicts the future facility overall efficiency according to the improvement plan from the facility overall efficiency (OEE) collected periodically, A facility management system is disclosed that calculates the future equipment load factor based on the predicted result, accumulates such information, and makes it useful for future equipment input plans.

JP 2002-182725 A JP 2008-015738 A

  Most of the conventional technology collects information related to the location, equipment, workpieces, etc. in the production system individually and manages the data items related to the collected production information at best. The data is displayed on the time axis in the order of, etc., and in order to display the aggregation result of each level of the data, the data is again aggregated and the result is displayed. In addition, the data to be displayed is fixed, and there is a problem that even data that is not actually necessary is displayed.

  SUMMARY OF THE INVENTION An object of the present invention is to provide a production information management system and method that can flexibly display managed productivity / reliability evaluation index information in a manner that is desired to be displayed only by setting.

  In order to solve the above problems, a production information management system of the present invention manages and displays information in a production information management system that manages information that is an evaluation index of productivity and reliability in a production system such as a key performance indicator (KPI). Data structure definition means for defining information used as an evaluation index of productivity / reliability in a hierarchical structure in XML format, and new productivity / reliability by performing arithmetic operations on data items related to the information of the defined data structure The inter-item calculation definition means for setting the data items of information to be used as the evaluation index, and the productivity / reliability evaluation index including the newly set information as the productivity / reliability evaluation index Data storage means for storing information in an XML data structure, data items defined in a hierarchical structure in the XML format, and evaluation of productivity and reliability to be displayed. An association means for associating data items of information serving as an index, and data items of the stored XML data structure as graph display candidates, and a GUI (graphic user interface) screen by a user from among the graph display candidates The graph display candidates are narrowed down by the search in, the narrowed graph display candidates are displayed on the GUI screen, and the user selects the displayed graph display candidates to acquire and display the data to be displayed via the association means Data display means.

  Further, the production information management system of the present invention provides data by time, place, and work for each data item of information that becomes an evaluation index of productivity / reliability to be managed and displayed by the definition by the data structure defining means having the above configuration. Information totaling means for preliminarily collecting collected information, information storage means for storing XML information in a hierarchical structure in an information storage structure using the time, place, and work as keys, and time, place on the GUI screen A graph display format setting means for setting a graph display format with any two or three vectors of the workpiece as an axis, and the time, place, work to be displayed in the graph display format set by the graph display format setting means. Information display means for acquiring and displaying information from the information storage means using as a key.

  Furthermore, in the production information management system of the present invention, the data structure defining means having the above structure hierarchically manages data items to be managed as information that serves as an evaluation index of productivity and reliability to be managed and displayed according to the production system of the company. Model definition means for defining as a top time model and an information model, the time model and the information model are displayed on a GUI screen, and a data item that a user wants to display on the GUI screen using the association means is displayed. It is characterized by registering the association.

  The production information management method of the present invention is a production information management method for managing information that is an evaluation index of productivity and reliability in a production system such as a key performance indicator (KPI). A data item of information that becomes a new productivity / reliability evaluation index by performing an arithmetic operation on a data item related to the information of the defined data structure by defining a process of defining information that becomes an evaluation index in a hierarchical structure in XML format A process for storing the information for the productivity / reliability evaluation index including the newly set information for the productivity / reliability evaluation index in an XML data structure, and the XML A process of associating a data item defined by a hierarchical structure of a format with a data item of information serving as an evaluation index of productivity / reliability to be displayed, and the stored The data item of the ML data structure is used as a graph display candidate, and the graph display candidate is narrowed down by the search on the GUI screen by the user from among the graph display candidates, the narrowed graph display candidate is displayed on the GUI screen, and the displayed graph And a process of acquiring and displaying data to be displayed by the user selecting a display candidate.

  In the production information management method of the present invention, in the above-described configuration, a process of defining information as an evaluation index of productivity / reliability to be managed and displayed in an XML hierarchical structure, and the management and display after the definition. For each data item of information serving as an evaluation index of productivity / reliability, a process of aggregating information collected by time, place, and work in advance, and an information storage structure using the time, place, and work as a key in XML A process of storing information in a hierarchical structure, a process of setting a graph display format about any two or three vectors of time, place, and work on the GUI screen, and the time, place, and work as keys. And a step of acquiring information from the information storage structure and displaying the information in the set graph display format.

  According to the present invention, the information storage method by the hierarchically structured XML with the data item at the top is adopted, and the data item that the user wants to display is linked on the GUI screen, so that the data that is to be managed and displayed is displayed. It can be displayed at an arbitrary section such as place, time, workpiece (manufacturing target), and at an arbitrary hierarchy in each vector. In addition, depending on the company's production system, an information model and time model with the data items for managing the productivity / reliability evaluation index information in the production system such as equipment operation status, downtime, and overall efficiency of the equipment in the hierarchy Since it can be defined by the user, it is possible to provide a production information management system that manages and displays production information that meets user needs.

It is a figure which shows schematic structure of the production information management system which concerns on embodiment of this invention. It is a figure which shows the detailed block structure of the production information management system which concerns on embodiment of this invention. It is a figure (the 1) which shows the further detailed block structure of the production information management system which concerns on embodiment of this invention. It is a figure (the 2) which shows the further detailed block structure of the production information management system which concerns on embodiment of this invention. It is a figure which shows the hierarchical structure in the various vectors in the information total which concerns on embodiment of this invention. It is a figure which shows the structural example of the information model which concerns on embodiment of this invention, and the structural example of a time model. It is FIG. (1) which shows the hierarchical data structure (XML) example of the data item which concerns on embodiment of this invention. It is FIG. (2) which shows the hierarchical data structure (XML) example of the data item which concerns on embodiment of this invention. It is FIG. (3) which shows the hierarchical data structure (XML) example of the data item which concerns on embodiment of this invention. It is a figure which shows the mode of the screen transition in the screen display functional block which concerns on embodiment of this invention. It is a figure which shows the screen structure of the template selection screen which concerns on embodiment of this invention, and the mode of the screen transition from this screen. It is a figure which shows the screen structure of the layout setting screen which concerns on embodiment of this invention, and the mode of the screen transition from this screen. It is a figure which shows the screen structure of the graph display screen which concerns on embodiment of this invention. It is a figure which shows the outline | summary of the RDB data acquisition process to the graph display screen which concerns on embodiment of this invention. It is a figure which shows the vector axis example of the graph displayed on the graph display screen which concerns on embodiment of this invention. It is a figure (the 1) which shows the example of an item of the primary data which concerns on embodiment of this invention. It is a figure (the 2) which shows the example of an item of the primary data which concerns on embodiment of this invention. It is a figure which shows the list of the item calculation definition which concerns on embodiment of this invention. It is a figure which shows an example of the general purpose view (VIEW) table which concerns on embodiment of this invention.

Hereinafter, embodiments of the present invention will be described in detail.
FIG. 1 is a diagram showing a schematic configuration of a production information management system according to an embodiment of the present invention. The production information management system according to the embodiment of the present invention shown in FIG. 1 is mainly composed of a Web-type client / server system interconnected via a network 1. A central information management apparatus 10 is provided, and an RDB (relational database) 20 that is centrally managed is placed in the Web-type server 5. In the RDB 20, data related to various controls / measurements, which are the basis of production management collected from the production site by the operation management / monitoring / control system 3 existing separately from the production management system of the present invention through the gateway 2 as raw data. Stored. The information management apparatus 10 processes production data by processing raw data stored in the RDB 20. This will be described in detail below.

  FIG. 2 is a diagram showing a detailed block configuration of the production information management system according to the embodiment of the present invention. 1 is divided into a data collection system 100 and a screen display system 200. The production information management system shown in FIG. More specifically, the data collection system 100 is divided into a data collection / aggregation function block 120 and an engineering function block 180.

  The data collection / aggregation function block 120 stores the data collected and processed by the function block 122 for executing the data collection process in an RDB (relational database) 124, and uses the information stored in the RDB 124 to execute various general-purpose views (generic view files). 126) is created. The function block 122 for executing the data collection processing is realized by the Web server 5 of FIG. 1, and the RDB 124 is unified with the RDB 20 of FIG. 1 as described above. As an example of various general-purpose views (including general-purpose view files) 126, FIG. 19 shows the configuration of a general-purpose view (VIEW) file for counting time information in units of months. In the engineering function block 180, the XML structure file 184 is generated by the engineering tool processing 182. Here, the XML file is defined as a file in which data composed of a key and a value called a tag (TAG) name is described in the present invention, and a file that can form a hierarchical structure by the tag name. It is a thing. The XML structure file 184 is generated according to this definition.

  On the other hand, the screen display system 200 includes a screen display function block 210. The screen display function block 210 displays various graphs that present productivity / reliability evaluation indices (including key performance indicators (KPI)) in the production system on the screen of the information management device 10 based on user settings. It has a function to display and execute. Here, the layout setting screen 230 is displayed on the screen of the information management device 10, the graph item candidates are displayed on the screen based on the XML structure file 184, and any productivity / The user sets whether to display the reliability evaluation index. Thereafter, a graph display screen (display button press) process 240 is performed when the user presses the display button. On the graph display screen (pressing the display button) 240, an SQL sentence creation process 250 by the user is performed. The screen / RDB relation table 251 is referred to by the SQL statement creation processing 250, and the data item name is converted into an RDB feed name. Next, data acquisition processing 260 from the RDB is performed, and graph data is acquired from the RDB 124. Thereby, a graph display screen (graph display) process 270 is performed. As a result, a graph is displayed on the screen of the information management apparatus 10.

  3 and 4 are diagrams showing a more detailed block configuration of the production information management system according to the embodiment of the present invention. 3 is a diagram (part 1) showing a more detailed block configuration of the production information management system, and FIG. 4 is a diagram (part 2) showing a more detailed block configuration of the production information management system. FIG. 3 shows details of the data collection / aggregation function block 120 and the engineering function block 180 outlined in FIG.

  In FIG. 3, an engineering function block 180 includes an information management index definition unit 170 having a time model customization unit 171 and an arithmetic expression definition unit 172, and a necessary primary data list based on the time model customized by the time model customization unit 171. A necessary primary data list creation function unit 173 to be created and output to the primary data management master 130 of the data collection / aggregation function block 120 and a time model customized by the time model customization unit 171 and based on the defined arithmetic expression Data structure and inter-item arithmetic expression creation function unit 174 for creating data structures and inter-item arithmetic expressions, and an inter-item arithmetic expression initial setting unit for initial setting of inter-item arithmetic expressions based on the created inter-item arithmetic expressions 175 and a data structure (XML) storage unit 184 that stores the created data structure.

  Here, the time model model customization means that the user customizes necessary primary data as a time model, as illustrated in FIG. 6B, and a list of necessary primary data based on the customized time model. The creation function unit 173 creates a necessary primary data list and outputs it to the primary data management master 130 of the data collection / aggregation function block 120 so that it is registered in the primary data management master 130. Next, primary data will be described. Primary data is defined in a table for each data type (status time, number of statuses, cycle time, production performance, production plan, constant data) as shown in FIGS. At the same time, whether or not to extract each management unit (time, place, work) is managed. Note that “MTBF” in the items of primary data shown in FIG. 17 is an abbreviation for Mean Time Between Failure, and “MTTR” is an abbreviation for Mean Time To Repair, and the MTBF target value and MTTR target value are constants. It is set by inputting as data from the setting screen.

  Further, as shown in FIG. 5, the data structure (XML) indicates a data structure having a hierarchical structure expressed in XML by various vectors in information aggregation. As a “location” hierarchical structure, a factory (site), a factory (area) ), Lines, processes, equipment (machines), and as a `` work (object) '' hierarchical structure, stratified into orders, lots, and items, and as a `` time '' hierarchical structure, year, month , Day, work shift (direct), hour, minute. Then, as illustrated in FIG. 6A, the data item aggregation level is expressed in a hierarchical structure expressed in XML as an “information model” developed by “location” × “work” × “time” described above. It is.

  Here, with regard to the data structure (XML), the time model shown in FIG. 6B and the management index not shown in FIG. (XML). 7 to 9 are views (Nos. 1 to 3) showing an example of a hierarchical data structure (XML) of data items according to the embodiment of the present invention. In FIG. 7 to FIG. 9, “CLASS” is used to represent the upper level of the hierarchy, data items are expressed by hierarchizing it, and “CLASS01” (see FIG. 7), “CLASS02” (see FIG. 8) between “CLASS”. ),..., “CLASS04”..., “CLASS07” (see FIG. 9), which are expressed in a hierarchical structure expressed in XML divided into time models and management indexes.

  Returning to FIG. 3, the data collection / aggregation function block 120 includes a primary data management master 130, a planned maintenance / production stop input unit 131 for defining the planned maintenance / production stop, and the defined planned Based on the information stored in the planned maintenance / production stop storage unit 132 for storing maintenance / production stop and the information stored in the primary data management master 130 and the information stored in the planned maintenance / production stop storage unit 132, the raw data A data collection function unit 133 that collects information from the RDB 21 and outputs the collected data to the primary data RDB 22, a constant data master 142 that stores constant data input / output from the data import / export unit 141, and between items The item definition defined in the calculation definition unit 144, and the item-to-item calculation expression initially set and output from the item-to-item calculation expression initial setting unit 175 as the item-to-item calculation definition are stored. Of the inter-item calculation storage unit 145, the constant data output from the constant data master 142, the primary data stored in the primary data RDB22, and the inter-item calculation definition output from the inter-item calculation definition storage unit 145. An inter-item calculation function unit 143 that performs an inter-item calculation based on each information and outputs the calculated data to the total data RDB23, information on the template VIEW design document 150, total data stored in the total data RDB23, and primary data RDB22 It has a VIEW creation function (script) unit 151 that creates a VIEW file based on the generated primary data, and a VIEW storage unit 160 that stores the created VIEW file.

  Here, FIG. 18 shows a list of inter-item calculation definitions. As shown in FIG. 18, in order to set information to be newly managed / displayed, for example, net operating time, an arithmetic operation (net operating time = net operating time = Automatic time + material waiting time + full load time). In addition to the above net operating time, the data defined by calculation between items includes speed loss time, actual operating time, abnormal time, total operating time, ..., load time, total time, ..., quality rate ,··and so on.

  In FIG. 4, the screen display function block 210 has a layout setting screen 230 for setting a layout to be displayed on the screen. The layout setting screen 230 is displayed on the screen when the user presses a “create new graph” button (described later) on the template selection screen 222 that enables selection of template information to be displayed on the screen from the template information (model) storage unit 220. The In the layout setting screen 230, all graph item candidates can be acquired from the data structure (XML) 184 shown in FIG. 3, and the general-purpose VIEW 160 from the preset screen / RDB relation table 251 and the graph to be displayed on the screen are displayed. Get definition with item. The graph items displayed on the screen are displayed in the graph item name column of the layout setting screen 230, and the graph items can be added / deleted by setting the graph item in the graph item name column. When a “Graph Display” button (described later) is pressed on the layout setting screen 230, the screen transitions to the graph display screen 300. These will be described in detail in the description of FIGS.

  On the graph display screen 300, the search condition setting unit 310 sets search conditions to narrow down graph items to be displayed in a graph. When the search condition setting unit 310 narrows down the graph items and clicks the display button, the processing moves to the SQL statement generation / execution unit 320. The SQL statement generation unit 232 generates an SQL statement based on the contents of the narrowed down graph items by the search condition setting unit 310 and the relationship definition of the screen / RDB relationship table 251 acquired on the layout setting screen 230, and generates the SQL statement. -It can be passed to the execution unit 320. The SQL statement generation / execution unit 320 can acquire data from the table of the aggregated data RDB23 through the general-purpose VIEW 160 by generating and executing the SQL statement based on the information set by the search condition setting unit 310. . Next, the SQL statement execution result expansion unit 330 expands data acquired from the table of the total data RDB 23 through the general-purpose VIEW 160. A data acquisition unit 350 having an XML structure is stored on the memory. After the SQL statement execution result is expanded in this way, a search result display process 340 is performed, and a graph is displayed as the search result. XML data is output from the search result display process 340 and stored in the XML data storage unit 360. Further, after storing in the data storage unit 360, a form XML output 400 is made as necessary.

  FIG. 10 is a diagram showing a state of screen transition in the screen display function block according to the embodiment of the present invention. When the “Graph Display” button 204 displayed on the menu screen 202 of FIG. 10 is pressed, the screen changes to the template selection screen 222. When the “Create new graph” button 224 is pressed on the template selection screen 222, the screen transitions to the layout setting screen 230. When the template file listed in the template selection field 228 is selected on the template selection screen 222 and the “template graph display” button 226 is pressed, the screen transitions to the graph display screen 300. On the other hand, on the layout setting screen 230, when the “Graph display” button 234 is pressed while the graph item to be displayed is displayed in the selected graph item name field 236, the screen transitions to the graph display screen 300, and the selected graph item name field The graph item displayed in 236 is displayed as a graph. On the layout setting screen 230, when a graph item to be added is set in the selected graph item name column 236 and the “add” button is pressed, the graph item set in the graph item name column 238 is added. When the “save template” button 302 is pressed on the graph display screen 300, the screen transitions to the template save screen 500. Further, when the “XML output” button is pressed, an XML file is output, and when the “layout setting” button is further pressed, the layout setting screen 230 is displayed. When the “save template” button 502 is pressed on the template save screen 500, the template is saved and the screen is changed to the graph display screen 300 when the save is completed.

  FIG. 11 is a diagram showing a screen configuration of a template selection screen according to the embodiment of the present invention and a screen transition state from the screen. The template selection screen 222 is a screen that is initially displayed when the data acquired by the user through the data collection process is displayed in a graph. There are the following two methods for displaying the graph.

(1) The user newly displays a graph.
By pressing a “create new graph” button 224, a layout setting screen 230 (see FIG. 12) is displayed. Information for performing a new graph display is set on the layout setting screen 230. When selecting multiple items, repeat the operation of right-clicking the item name you want to add.

(2) Manipulate the factory-defined template or user-defined template.
In this case, information on the template file (file storing data necessary to display graphs such as X-axis graph items, Y-axis graph items, graph types, and graph conditions) is displayed in a list in the template selection field 228, By selecting a template file to be output and pressing a “template graph display” button 226, the selected template file is displayed as a graph on the screen of the graph display screen 300. When adding a plurality of items, it is checked whether the unit information (second, number,%) for each item stored in the XML structure file 184 is the same.

In addition, a template file is selected in the template file list, and a “template graph deletion” button is pressed to delete the selected template file.
FIG. 12 is a diagram showing a screen configuration of the layout setting screen according to the embodiment of the present invention and a screen transition state from the screen. When the “create new graph” button 224 is pressed on the template selection screen 222 displayed on the upper left side of FIG. 12, default values are set on the layout setting screen 230. The contents of the default values are “graph name” without setting, “X-axis item selection” with date selected, “graph item” with date, and “data unit” with no selection. In addition, a graph item name is not set in “Y1 axis graph item name selection” 233, “Y2 axis graph item name selection” 235, and “table item name selection” 237. When the “layout setting” button is pressed on the graph display screen 300 displayed on the lower left side of FIG. 12, the contents set on the graph display screen 300 of the caller are displayed on the layout setting screen 230. .

  Next, using the data selected in the X axis item 231, Y1 axis graph item name selection column 233, Y2 axis graph item name selection column 235, and table item name selection column 237 on the layout setting screen 230, the right side of FIG. Graph display is performed on the graph display screen 300 shown in FIG. This will be described later.

  Also, the title of the graph to be displayed on the graph display screen 300 is specified in the graph name in the graph item selection field displayed at the top of the layout setting screen 230. Furthermore, in the X-axis item selection field of the X-axis item 231, a graph item to be displayed on the X-axis is designated by radio button from among location, work, date, and failure factor. In the Y1 axis graph item name selection field 233, the Y2 axis graph item name selection field 235, and the table item name selection field 237, when you left-click the tab with the respective titles, the selection graph item name field 233 displays the XML structure file. And display the graph item candidates as a tree. Here, the tree display order is the content order set in the XML structure file. The operation during tree display is as follows. (1) Double-click an item to open a child item. (2) With the child item displayed, double-click the item to close the child item. In the initial display, the top item of the tree is displayed. Further, the graph item name field 238 displays a list of graph item names to be displayed on the graph.

  The setting of the graph item name in the graph item name column 238 is performed in the following procedure. (1) In the selected graph candidate name field 236, right-click an item name to be displayed in a graph and select it. (2) When the add button 239 is pressed, a specified name is set in the graph item name field 238. If already set, exit without registering. The deletion of the graph item name from the graph item name column 238 is performed in the following procedure. (1) Right-click the graph item name you want to delete in the graph item name field 238 and select it. (2) By pressing the delete button, the specified names listed in the graph item name field 238 can be deleted. When the “Graph display” button 234 on the layout setting screen 230 is pressed, the contents set on the screen are saved in a work template file (not shown) and the data is reflected on the graph display screen 300. .

  The graph item of the X-axis item 231 is selected from the radio button location, work, date, and failure factor. When selection is performed using a radio button, a data item name and a data unit are determined as follows according to the selected button content. (1) When a place is selected, data item selection candidates are a factory, a factory, a line, a process, and a machine. Data units are month, day, direct, and hour. Furthermore, Y1-axis gragg items, Y2-axis graph items, and table items are determined by the contents of the XML structure file. (2) When a workpiece is selected, data item selection candidates are model, lot, and batch. Data units are month, day, day, hour. Y1 axis graph items, Y2 axis graph items, and table items are determined by the contents of the XML structure file. (3) When a date is selected, the data item selection candidates are month, day, day, hour. In addition, the data unit is not provided because it is also a month, a day, a day, and a time. Y1 axis graph items, Y2 axis graph items, and table items are determined by the contents of the XML structure file. (4) When a failure factor is selected, the data item selection candidate becomes a failure factor. Data units are month, day, day, hour. Y1 axis graph item, Y2 axis graph item, and table item are total time and total number.

  Next, if you specify a graph candidate in the graph item name field (not shown) on the Y1 axis graph item name selection tab 233 and display the graph, a graph showing the unit of the 1-axis scale on the graph screen is displayed. . Also, when a graph candidate is designated in the graph item name field (not shown) of the Y2 axis graph item name selection tab 235 and displayed as a graph, a graph displaying the unit of the 2-axis scale on the graph screen is displayed. Furthermore, when a graph candidate is designated in the table item name column (not shown) of the table item name selection tab 237 and displayed in a graph, the table is displayed at the bottom of the graph screen.

  FIG. 13 is a diagram showing a screen configuration of a graph display screen according to the embodiment of the present invention. In the graph display screen shown in FIG. 13, the data collected and aggregated by the data collection / aggregation function block 120 of the data collection system 100 in FIG. 2 is displayed in various graph patterns and graph types. Refer to FIG. 15 for graph display examples of various graph patterns and graph types.

  When data to be displayed in a graph is acquired from the total data RDB 23 (see FIG. 3) via the general-purpose view table 160, data that becomes a narrowing condition is set in the graph display screen 300. In this case, for example, when narrowing down the narrowed-down items on the location, the narrowed-down item “manufacturer / factory / line / process / machine” on the location is selected from the narrowed-down combo box 303 on the location. Data to be displayed is acquired from the total data RDB23. When narrowing down items to be narrowed down on a work, “model / lot / batch” is selected from a narrowing down combo box 304 on the work. Further, when narrowing down the time narrowing items, the date designation field 305 is designated by specifying a date period or a direct date. In the initial display, the content described in the work template file is the search condition (narrowing condition) section at the top of the graph display screen 300 (manufacturer / factory / line / process / machine / model / lot / year / month / date period) ) Reflected in 303-305.

  In the narrow-down combo box 304 on the work, model / lot / batch is displayed according to the work information defined in the environment setting file (not shown). However, when a work is selected by the X-axis item selection radio button in the X-axis item 231 of the layout setting screen 230, the work item specified by the data item is displayed. This is because the model / lot / batch is not specified at the same time.

  The period specification content in the date specification field 305 is determined by the data unit of the X-axis item 231 on the layout setting screen 230. For example, if the data unit of the X-axis item 231 is (1) "Month" or "Day", only the date, (2) If "Direct", the date and time (work shift 1-3) (3) In the case of “hour”, the date and time are displayed.

  In the layout setting screen 230, if the graph item set in the Y1 axis graph item selection field 233 and the graph item set in the Y2 axis graph item selection field 235 are set, the set graph item is displayed. In order to correct this item, the “layout setting” button on the graph display screen 300 is pressed to change to the layout setting screen 230. In any case, the graph item displayed in the graph item selection field 233 or the like becomes the Y-axis data value when the graph is displayed.

  Next, the graph display content control part provided at the center of the graph display screen 300 will be described. The 1-axis candidate display field 306, 2-axis candidate display field 307, detailed display 308, 1-axis cumulative broken line, large order, 1-axis graph type, 2-axis graph type, respectively, provided in this graph display content control part By specifying, the contents of the graph display can be controlled as follows. That is, (1) the contents of the items necessary for displaying the item selected in the one-axis candidate display field 306 by the designation of the detailed display 308 are displayed in a graph. (2) The designation of the 1-axis cumulative broken line is added to the graph display content so that the accumulated value of the item selected in the 1-axis candidate display field 306 is displayed as a broken line display graph (not performed during detailed display). (3) The designation in the descending order sorts the items selected in the one-axis candidate display field 306 in the descending order with respect to the graph display contents. If not specified here, the sequence is as follows: (a) Name order when the X axis is a place, (b) Name order when the X axis is a workpiece, and (c) Date when the X axis is a date, in order of oldest date. (4) To specify the uniaxial graph type, change the uniaxial graph type for the graph display contents (default: bar graph). (5) To specify the biaxial graph type, change the biaxial graph type for the graph display contents (default: line graph). In order to reflect these settings in the graph display, it is reflected by pressing the “Display button” 309 with the item selected in the 1-axis candidate display field 306 and the 2-axis candidate display field 307. Is not reflected.

  The graph name indicating the contents of the screen displayed at the center of the graph display screen 300 is the graph name set in the graph name column on the layout setting screen 230 or the like. In order to correct this item, a “layout setting” button is pressed to change to the layout setting screen 230.

  When the “display button” 309 on the right side of the graph display screen 300 is pressed, graph data is acquired from one general-purpose view table and displayed as a graph. At this time, an SQL sentence is created using the screen / RDB relation table 251 (see FIG. 2). When the “display button” 309 is pressed, the graph value and legend are displayed simultaneously with the graph display. The graph value displays only the Y-axis value. In addition, the legend displays the graph item names on the right side of the graph divided into one axis and two axes (see FIG. 15). The X-axis size of the graph is fixed, and the items on the X-axis are displayed within that size.

  As shown in the bar graph display example shown in the graph display screen 300 of FIG. 13, the bar width can be changed by operating the bar width change field at the bottom of the screen while the bar graph is displayed (default: 80% , Range: 1-100). If the graph value is not displayed, the Y-axis value of the graph is not displayed if a check mark is placed in the check box for the item that does not display the graph value at the bottom of the screen. If the legend is not displayed, the legend is not displayed if a check mark is added to the check box of the item that does not display the legend at the bottom of the screen.

  Further, when a table item is specified in the table item column of the table item name selection tab 237 of the layout setting screen 230 shown in FIG. 12 and the “graph display” button 234 is pressed, the graph display screen 300 in FIG. A table is displayed (not shown). In the “row” in the table, the table item name specified in the table item column of the table item name selection tab 237 of the layout setting screen 230 is displayed in the table. In the “column” in the table, the item of the X axis is displayed. The size of the table is fixed, and if a row or column item larger than that size is displayed, a scroll is displayed to display a value that is not displayed.

  FIG. 14 is a diagram showing an outline of the RDB data acquisition process on the graph display screen according to the embodiment of the present invention. In the embodiment of the present invention, as described above, the SQL sentence is created by the SQL sentence creation 250 using the screen / RDB relation table 251 shown in FIG. By creating the SQL statement, the data extracted from the RDB 20 on the graph display screen 300 is displayed on the Web screen (the graph display screen 300 of the Web client 4). In the production information management system according to the present invention following FIG. 1, data is exchanged between the Web client 4 and the Web server 5, and is shown in FIG. On the graph display screen 300, an RDB data acquisition request is passed to the servlet processing function 25 of the Web server 5. A Servlet is a program that runs on a server that dynamically generates HTML documents for web pages using Java (registered trademark), or its specifications. It is widely known to the person. In the servlet processing function 25, a reusable software component written in JavaBean (Java) is activated to perform data extraction processing of the RDB 20 and memory storage processing of acquired data. Then, the result is transferred from the servlet processing function 25 to the graph display screen 300 of the information management apparatus 10 in the Web client 4.

As an example, assuming that “location” is selected for the X-axis item 231 on the layout setting screen 230, when the “graph display” button 234 on the layout setting screen 230 is pressed, the screen transitions to the graph display screen 300. Then, on the graph display screen 300, extraction processing into the RDB is executed by the following processing. That is,
(1) Extract data from combo box 303 of location (manufacturer / factory / line / process / machine), and select SQL <location item field name> FROM <table name> GROUP <location item field in SQL statement Name> Describe ORDER BY <Field item field name>.

  (2) In the extraction of data to be displayed in the graph, describe SELECT <field name of search condition item>, <field name of Y axis item> FROM <table name> WHERE <field name of search condition item> in the SQL statement. .

  (3) When extracting table data, describe SELECT <field name of table item> FROM <table name> WHERE <field name of search condition item> GROUP <field name of table item> in the SQL statement.

  In the case of (1) and (3) above, the result is stored in the memory as List data, but in the case of (2), it is stored in the memory using the DOM (XML file processing class) function. . By holding the result data in this way, there are the following advantages. That is, since data can be held in the memory in units of location, work, and date, the data can be held in the memory without duplication. Further, data can be acquired without referring to all records, and efficient data extraction can be performed. The memory data stored by the servlet in this way is transmitted to the Web client 4 and displayed on the graph display screen 300 as a graph.

  Here, the exchange of data between the data structure XML file 184 and the graph display screen 300 will be described again. In the embodiment of the present invention, the data structure XML file 184 is transferred to the data structure XML file 184 during the exchange of data between the client and the server in the Web format. File generation and data structure Extraction of data from the XML file 184 is performed. As described above with reference to FIG. 14, the process of fetching data from the data structure XML file 184 onto the Web screen (layout setting screen 230, graph display screen 300) is performed using a DOM function. That is, an XML structure file reading operation is performed on the layout setting screen 230 as described above, and an initial screen display (on the Web client 4) is performed. The XML structure file is stored on the client memory using the DOM function. In addition, an XML structure file writing operation is performed on the graph display screen 300 to perform initial display (on the servlet). In this case, the XML structure file is stored on the server memory using the DOM function. When generating a file to an XML structure file on the graph display screen 300, the XML file is saved (on the Servlet). Then, the data of the DOM function stored in the memory by the data processing for displaying the graph is output to a file on the Web client 4 side (the file output processing uses a JAVA input / output function).

  FIG. 15 is a diagram illustrating an example of a vector axis of a graph displayed on the graph display screen according to the embodiment of the present invention. In FIG. 15, (a) is an example in which time is displayed on the X axis and N types of data are displayed on the Y axis in a bar graph, and (b) is a bar graph in which data for each location N is displayed on the X axis and the workpiece. For example, (c) shows the location on the X axis, two types of data as a single axis data on the Y axis in a bar graph, and one type of data as a biaxial data in a line graph, and (d) FIG. 5 shows an example in which the failure factor is displayed on the X axis, the data is displayed as a bar graph in descending order as the 1 axis data of the Y axis, and the accumulated line graph is displayed as 2 axis data.

  FIG. 19 shows an example of a general-purpose view (VIEW) table according to the embodiment of the present invention. The selection of the general-purpose VIEW table is determined by the content of the “X-axis item selection field” in the X-axis item field 231 of the layout setting screen 230 described above. (The workpiece is specified as “model” unless a workpiece is specified in the X-axis item selection field. In the case of workpiece specification, the workpiece item specified in the data item is used.) General view (VIEW ) The table shows a monthly summary general-purpose view (a table that summarizes the data collected and aggregated for each month). When the location, work, or date is selected and the data unit specifies the month Chosen. The data to be collected and aggregated includes the factory code, factory, line code, machine, product name, lot, date, actual operation time, average actual operation time, minimum actual operation time, maximum actual operation time, and net Total operating time, net operating time average value, net operating time minimum value, net operating time maximum value, speed loss time total, speed loss time average value, speed loss time minimum value, speed loss time maximum value, etc. can be set it can. The total time, average value, minimum value, maximum value, and the like are values obtained by collecting collected data.

  In addition to the monthly summary general-purpose view shown in the example, the present invention uses a daily summary general-purpose view (a table summarizing data collected and collected every day) and a direct-summary general-purpose view (data collection and data summarization every day). Data summary table), hourly generalized VIEW (table that summarizes data collected and aggregated for each hour), monthly alarm aggregated generalized VIEW (monthly alarm status data collected and data aggregated Summary table), daily alarm summary general-purpose VIEW (table that collects data when the alarm state is collected and collected every day), direct alarm summary general-purpose VIEW (collects data during the alarm state every day and collects data) Table), etc., but these contents can be inferred based on the monthly aggregate general view shown in the figure, so the detailed explanation here is To Kukoto.

1 Network 2 Gateway 3 Operation Management / Monitoring / Control System 4 Web Client 5 Web Server
10 Information management device
20 RDB (Integrated DB)
21 Raw data (RDB)
22 Primary data RDB
23 Total data RDB
100 data collection system
120 Data collection and aggregation function block
122 Data collection processing
124 RDB
126 General-purpose VIEW
130 Primary data management master
131 Planned maintenance / production stop input section
132 Planned maintenance / production stop storage
133 Data collection function
141 Data import / export section
142 Constant data master
143 Calculation function between items
144 Inter-item calculation definition part
145 Inter-item calculation definition storage
150 Model VIEW design document
151 VIEW creation function (script) part
160 VIEW storage
170 Information management index definition section
171 Time model customization section
172 Formula definition part
173 Required primary data list creation function
174 Data structure and item formula creation function
175 Initial calculation part between items
180 Engineering Tool Function Block
182 Engineering tool processing
184 XML structure file (data structure XML)
200 screen display system
210 Screen display function block
220 Template information (model) storage
222 Template selection screen
230 Layout setting screen
232 SQL sentence generator
240 Graph display screen (when the display button is pressed)
250 SQL statement creation processing
251 Screen / RDB relationship table
260 Data acquisition processing from RDB
270 Graph display screen (when graph is displayed)
300 Graph display screen
310 Search condition setting section
320 SQL statement creation / execution part
330 SQL statement execution result expansion part
340 Search result display processing
350 XML structure data acquisition unit
360 XML format data storage
400 Form XML output

Claims (6)

In a production information management system that manages information that is an evaluation index of productivity and reliability in production systems such as key performance indicators (KPI),
A data structure defining means for defining information that is an evaluation index of productivity and reliability to be managed and displayed in a hierarchical structure in XML format;
An inter-item operation defining means for setting a data item of information that becomes a new productivity / reliability evaluation index by performing an arithmetic operation on the data item related to the information of the defined data structure,
Data storage means for storing information that becomes the evaluation index of productivity / reliability in an XML data structure including information that becomes the evaluation index of productivity / reliability newly set;
A linking means for linking a data item defined by the XML hierarchical structure and a data item of information serving as an evaluation index of productivity / reliability to be displayed;
Data items of the stored XML data structure are used as graph display candidates, and the graph display candidates are narrowed down by searching on the GUI (Graphic User Interface) screen by the user from the graph display candidates, and the narrowed graph display candidates are selected. A data display means for acquiring and displaying data to be displayed via the linking means by a user selecting a displayed graph display candidate displayed on the GUI screen;
A production information management system characterized by comprising: The data structure defining means is a model that defines data items to be managed as information that is an evaluation index of productivity and reliability to be managed and displayed according to the production system of the company as a time model and an information model having a hierarchical top. Having definition means,
2. The production information management system according to claim 1, wherein the time model and the information model are displayed on a GUI screen, and a data item to be displayed by a user is linked and registered on the GUI screen using the linking unit. . By means of the definition by the data structure definition means, for each data item of information that becomes an evaluation index of productivity and reliability to be managed and displayed, information aggregation means for preliminarily collecting information collected by time, place, work, and
Information storage means for storing XML information in a hierarchical structure in the information storage structure with the time, place, and work as keys;
On the GUI screen, a graph display format setting means for setting a graph display format centered on any two or three vectors of time, place, and work;
Information display means for acquiring and displaying information from the information storage means using the time, place, and work as keys to display in the graph display format set by the graph display format setting means;
The production information management system according to claim 1, further comprising: By means of the definition by the data structure definition means, for each data item of information that becomes an evaluation index of productivity and reliability to be managed and displayed, information aggregation means for preliminarily collecting information collected by time, place, work, and
Information storage means for storing XML information in a hierarchical structure in the information storage structure with the time, place, and work as keys;
The XML information stored in the information storage means is used as a graph display candidate, and the graph display candidate is narrowed down by a search on the GUI screen by the user from among the graph display candidates, and the narrowed graph display candidate is displayed on the GUI screen. The management data item / display data item that associates the management data item in the XML information with the display data item of the information that becomes the evaluation index of productivity / reliability by the user selecting the displayed graph display candidate Linking means;
After linking by the management data item / display data item linking means, the management data item in the XML information displayed on the GUI screen is selected, and the data of the tree data item expanded to the management data item is selected. Expanded data display means to be displayed;
The production information management system according to claim 1, further comprising: In a production information management system that manages information that is an evaluation index of productivity and reliability in production systems such as key performance indicators (KPI),
A process of defining information that is an evaluation index of productivity and reliability to be managed and displayed in an XML hierarchical structure,
A process of setting a data item of information to be a new productivity / reliability evaluation index by performing arithmetic operations on the data item related to the information of the defined data structure;
Storing the information that becomes the productivity / reliability evaluation index including the newly set productivity / reliability evaluation index in an XML data structure;
A process of associating the data items defined in the XML hierarchical structure with the data items of the information to be displayed as the evaluation index of productivity and reliability;
Data items of the stored XML data structure are set as graph display candidates, and the graph display candidates are narrowed down by searching on the GUI screen by the user from among the graph display candidates, and the narrowed graph display candidates are displayed on the GUI screen. The process of acquiring and displaying the data to be displayed by the user selecting the displayed graph display candidate,
Including production information management method. A process of defining information that is an evaluation index of productivity and reliability to be managed and displayed in an XML hierarchical structure,
After the definition, for each data item of information serving as an evaluation index of productivity and reliability to be displayed and managed, a process of previously collecting information collected by time, place, work, and
Storing XML information in a hierarchical structure in the information storage structure using the time, place, and work as a key;
On the GUI screen, a process of setting a graph display format centering on any two or three vectors of time, place, and work;
A process of acquiring information from the information storage structure using the time, place, and work as a key and displaying the information in the set graph display format;
The production information management method according to claim 5, further comprising: