KR100756005B1 - Reinforced optimization service system and method thereof, and recording media storing computer program for the method - Google Patents

Abstract

The present invention relates to a reinforcing bar service system, a method, and a recording medium for recording a computer program for the method. The present invention relates to a reinforcing bar data based on the stored reinforcing bar data. Driving a reinforcing bar optimization service program that calculates and combines and calculates an optimized reinforcing bar assembly drawing and work flow chart; Opening the rebar optimization service window by driving the rebar optimization service program; Creating a work process room in the rebar optimization service window and inputting and storing rebar data for each item; Calculating an optimized rebar assembly drawing and a work drawing by combining and calculating the input rebars based on the reinforcing bar data stored in the work processing room; And storing and outputting the calculated reinforcing bar assembly drawing and work drawing on a monitor screen, thereby combining and calculating all reinforcing bars input based on data databased by a computer program for the processing of the reinforcing bar during rebar construction. The optimized work flow chart can be calculated.

Description

REINFORCED OPTIMIZATION SERVICE SYSTEM AND METHOD THEREOF, AND RECORDING MEDIA STORING COMPUTER PROGRAM FOR THE METHOD}

1 is a block diagram of a rebar optimization service system according to the present invention

2a and 2b is an overall flow chart showing a rebar optimization service method according to the present invention

3 is a flowchart illustrating a method of inputting reinforcing bar data in FIG.

4 is a flowchart illustrating a method of optimizing a database by rebar data in FIG. 2;

5 is a flowchart illustrating a method of optimizing reinforcing bar data in FIG.

6 is a flowchart illustrating a method of outputting a screen in FIG.

7 is a view showing a rebar optimization service window window screen according to the present invention

8A to 8E are diagrams illustrating a menu window screen of FIG. 7.

FIG. 9 is a diagram for describing a method of creating a work process directory in the work process window window of FIG. 7; FIG.

10A and 10B illustrate an example of creating a work process directory of FIG. 9.

FIG. 11 is a diagram illustrating a rebar selection window window screen of FIG. 7. FIG.                 

FIG. 12 is a diagram illustrating a rebar data input window screen of a rebar icon provided in the rebar selection window window of FIG. 11; FIG.

FIG. 13 is an explanatory diagram for describing a method of inputting reinforcing bars divided in the reinforcing bar data input window of FIG. 12; FIG.

14 and 15 illustrate screens in which rebar data input to a work process directory is displayed in a rebar window window and an output window window of a rebar optimization service window window;

FIG. 16 illustrates a screen of an optimization option window activated by selection of an optimization menu in the menu window of FIG. 10C; FIG.

17 is a diagram illustrating a guide window screen indicating that an optimization operation is being executed.

FIG. 18 is a diagram illustrating an output window screen of reinforcing bar items in the output window window of FIG. 7; FIG.

FIG. 19 is a view illustrating an output window screen of an assembly drawing item in the output window window of FIG. 7; FIG.

20 is a view illustrating an output window screen of a result item in the output window window of FIG. 7;

FIG. 21 is a diagram illustrating a screen of a price calculation table activated by selection of a price calculation table menu in the menu window of FIG. 8E; FIG.

<Explanation of symbols for main parts of the drawings>

10: input device 12: keyboard                 

14: mouse 20: output device

22: monitor 24: printer

30: main computer 32: storage device

34: rebar optimization application 40: database (DB)

50: rebar cutting device

100: rebar optimization service window window 110: menu window

120: work process window window 130: rebar selection window window

140: rebar window window 150: output window window

230: Rebar type selection window 231: Rebar window window

232: Rebar type selection window 233: Rebar thickness selection window

234: Rebar data input window 235: Rebar cutting window window

236: Auto cut selection button 237: Joint number display window

238: Reinforcing bar data input field 239a: Selection button

239b: Cancel button 250: Optimization Options window

251: Target selection window to optimize 252: Select all button

253: reverse selection button 254: deselect button

255: Target selection unit 256: Rebar selection window to be used

257: select all button 258: basic selection button

259: optimization precision display unit 260: execution button

261: cancel button 262: save button                 

270: Information window during optimization 271: Progress display unit

272: search display unit 273: quantity display unit

274: cancel button

The present invention relates to a reinforcing bar service system, a method, and a recording medium for recording a computer program for the method. Particularly, the present invention relates to a reinforcing bar service process. The present invention relates to a method of rebar optimization service for combining and calculating an optimized work flow chart, and a recording medium recording a computer program for the method.

At the current construction site, the rebar processing shape is calculated and recorded and managed by hand. This fact requires the manual management of the rebar information, which makes it difficult to calculate the total quantity by rebar specifications or by length of reclamation. This resulted in the loss of rebar.

In Korea, steel bars are producing 6m, 7m, 8m, 9m, 10m, 11m, and 12m in total, including the types of rebars in stock. At the reinforcing site, 8m and 10m precision rebars are used a lot.

At the rebar construction site, it receives a design drawing (shop drawing) and processes the rebar one by one in the shape of the rebar assembly drawing. At this time, the portion of the reinforcing bar is generated when cutting the reinforcing bar one by one. Each reinforcing bar does not have the same number, so if the work volume reaches a few hundred tons, the work order cannot be planned in advance.

Therefore, when the standard reinforcing bar is cut and used according to the size of each site, it is cut and the remaining bar is discarded without being used again. At this time, the rebars cut and discarded increase as the quantity and items of rebars increase, so that the loss ratio of rebars increases by that amount.

The present invention has been made to solve the above problems, and an object of the present invention is to optimize the work flow chart by combining and calculating all the reinforcing bars inputted on the basis of data databased by a computer program for the processing of the reinforcing bars The present invention provides a recording medium recording a rebar optimization service system, a method thereof, and a computer program for the method.

In addition, another object of the present invention is to store and store a database of all types of rebars on the market by combining and calculating the input reinforcement data when designing the rebar assembly and work flow diagram to select and place the optimized rebar In addition, the present invention provides a recording medium that records a rebar optimization service system that can greatly reduce the loss rate of reinforcing bars, a method thereof, and a computer program for the method.

Reinforcing bar optimization service method of the present invention for achieving the above object, (a) the reinforcing bar optimized by combining the input reinforcement data on the basis of the stored reinforcement data, and storing the input reinforcement data by database Driving a rebar optimization service program for calculating an assembly drawing and a work flow chart; (b) generating a rebar optimization service window window when the rebar optimization service program is driven; (c) Selecting a work process room creation menu in the rebar optimization service window creates a work process room, stores reinforcing data by item in the work process room, and generates a reinforcing table representing the stored reinforcement data by item. Steps; (d) When reinforcing bar data is input through the reinforcing bar data input menu of the rebar optimization service window window, the input bar data is cut based on the bar data stored in the work process room, and then the pieces of each bar are circulated one by one. Optimizing the total reinforcement length by selecting a method in which the loss rate per base reinforcing bar length is low by combining the number of pieces per piece; (e) classifying the reinforcing bar data performed by the optimization operation into complexity, displaying the shape of the bar as a simple picture, storing it as a BMP file, encrypting the BMP file format, converting the file into a unique file, and Storing the BMP file in a designated work process room, reading the BMP file stored in the work process room, interpreting a mark, and outputting the BMP file to a screen or a printer to design a rebar assembly diagram; (f) calling up the result value of the reinforcing bar data which has performed the optimization operation, classifying the reinforcing bar according to the diameter according to the result of the reinforcing bar data, sorting the sorted bar according to the length per diameter, and The same items are omitted from the reinforcing bars and the number is increased, the overlapping items of the reinforcing bars are omitted, the number is increased, and the total amount and the loss ratio of the used reinforcing bars are obtained. Repeating until then outputting information on the total use and the loss rate to design a work flow diagram; (g) calculating a price of the rebar required by the work flow chart by using a price calculation table; And (h) storing the calculated reinforcing bar assembly drawing and work flow chart and outputting at least one of a file, a monitor screen, and a printer.
The reinforcing bar data stored in the work process room is classified and stored in units of diameter of the bar.
The rebar work flow chart optimization service method includes: copying and changing rebar data to be changed when changing rebar data stored in the work process room; Selecting one of the reinforcement data and the changed reinforcement data stored in the work process room by an optimization operation; And newly storing one reinforcing bar data selected by the optimization operation in the work process room, wherein the optimization operation comprises: a first step of organizing the reinforcing bar data by diameter suitable for a substitution mode; A second step of specifying an optimization option for the substitution mode after the step; A third step of performing substitution mode optimization after the step; A fourth result of temporarily storing the result value when the loss is small compared to the existing result value, and repeating the second and third steps until the loss is smaller than the existing result value. Steps; A fifth step of organizing the reinforcing bar data by diameter to be suitable for a combined mode; A sixth step of specifying an optimization option for the combined mode after the step; A seventh step of performing combined mode optimization after said step; An eighth step of repeating the sixth and seventh steps until the result value of the combination mode optimization is smaller than the existing result value and the result value is temporarily stored; Steps; A ninth step of comparing the result value of the substitution mode with the result value of the combination mode to select and store a value having a small loss; And a tenth step of repeating the first to ninth steps when there are reinforcing bar data having different diameters.
The work process room is characterized in that it is possible to create, rename, delete, copy, paste the room.
The rebar work flow chart optimization service method includes: automatically cutting a join to a default value when there is a join to a reinforcing bar while inputting the rebar data into the work process room; Adding the input reinforcing bar data and reinforcing bar data stored in the work room; Updating the screen output again by the added rebar data; And storing the added reinforcing bar data in the newly created work process room.
The rebar optimization service window window, the menu window having a menu of various functions; A work process window window for making the work process room; A rebar selection window window having a plurality of rebar data to select rebar data to be input to the work process room; A reinforcing bar window each showing an assembly diagram of the reinforcing bar data input to the work process room; And an output window window for displaying the assembly diagram, the work flow chart, the price calculation table, and the reinforcement table by item selection.
The menu window, 'New file ( N )' menu to create a new file; 'Open ( O )' menu to open an existing file; 'Open after' menu to trap existing open files; 'Save ( S )' menu to save the work file; Save (A) As "menu to save under a different name; 'Save selected rooms only' menu to save only the selected room; 'Print ( P )' menu to print results; A 'print preview ( V )' menu for previewing the printout screen; 'Print Setup ( R )' menu for setting options related to printing; And a file menu having a 'end ( X )' menu for terminating the program.
The menu window includes a 'copy all design values to the changed value' menu to create a changed value identical to the design menu; 'Copy Only Items Not Changed' menu (V), which compares the design and the changed values and copies only the other items to the changed values; And a "change value delete ( D )" menu for deleting all existing change values.
The menu window may include an 'Optimization option ( L )' menu for opening a dialog box for selecting an option during optimization; And an optimization menu having an 'optimization operation execution ( P )' menu for performing optimization.
The menu window may include a 'frequently used rebar window' menu for opening a tool for selecting and arranging rebars frequently used when inputting a rebar shape; 'Rebar image / line view mode' menu that selects the rebar image displayed on the entire screen as a line or an image; 'View Design Value Changes' menu, which selects to display the design value changes at once in the output screen; 'Find Assembly ( F )' menu to search by drawing name when there are many bars in the rebar window; 'Font Settings' menu to change the font displayed on the screen; And a setting menu having a 'environmental setting' menu for setting margins, output colors, and the like.
The menu window is a 'Calendar ( C )' menu showing a calendar; On a weekly basis to manage the schedule, week schedule notes (N) 'menu;'OMP file viewer' menu to read only results; 'Analyze chart view' menu to analyze the results by the usage ratio; And a basic work tool menu having a 'price calculation table' menu for outputting an order table relating to costs required for the result.
The work process window window includes a menu for creating a room for making the work process room; A 'preventing' menu for erasing the created work process room; A 'name change' menu for changing a name of the created work process room; 'Copy ( C )' menu to copy files; 'Paste ( P )' menu to paste files; And a 'selection room storage' menu for storing the selection room.
The rebar selection window window may include a plurality of rebar icons each having rebar data input to the work process room.
The plurality of reinforcing bar icon is characterized in that broken down according to the type of reinforcing bar, such as straight line, connecting straight line, L type, c type, LR type, dish type.
When the rebar icon is clicked, a rebar data input window for inputting rebar data is opened.
The reinforcing bar data input window may include: a reinforcing bar window configured to display reinforcing bars input in each work process; A rebar type selection window for selecting the rebar type; Rebar thickness selection window for selecting the thickness of the reinforcing bar; A reinforcing bar data input box for inputting the reinforcing bar data; Reinforcing bar cutting window showing the length to be cut and the shape to be processed; An auto crop select button for selecting auto crop; Joint number display window for displaying the number of joints; A rebar cutting data input box for inputting rebar cutting data; And a select button and a cancel button.
The reinforcing bar data field includes reinforcing drawing names (Name), lengths of elements (a, b), total number of reinforcing bars (N), and lengths (Join) joined when cutting the bar.
The rebar window window is characterized in that the menu window, including reinforcing the shape of the rebar, modifying the rebar, delete the reinforcing bar is opened by pressing the right button of the mouse on the rebar to apply the command.
The optimization option window opened by clicking on the optimization option ( L ) menu may include: an optimization target selection window for selecting an optimization target; Respective buttons for selecting all, inverting and deselecting; An object selection unit for selecting a design value and a change value; Rebar selection window to select rebar to use; Select buttons, each button for basic selection; An optimization precision display unit for displaying the optimization precision; And buttons for executing, canceling, and storing.
The method may further include a guide window during optimization indicating that the optimization operation is in progress.
Hereinafter, with reference to the accompanying drawings will be described in detail an embodiment of the present invention.

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1 is a block diagram of a rebar optimization service system according to the present invention.

The rebar optimization service system, as shown, an input device 10 having a keyboard 12 and a mouse 14, an output device 20 having a monitor 22 and a printer 24, and A main computer 30 having a storage device 32 connected to an input device 10 and the output device 20 and having a rebar optimization application 34 installed therein, and data connected to the main computer 30. It is configured to include a database (DB) 40 for storing the, and the rebar cutting device 50 connected to the main computer 30.

The input device 10 inputs reinforcing bar data using the keyboard 12 and the mouse 14 to design a rebar assembly diagram and a work flow chart.

The output device 20 outputs the rebar optimization service window window 100, which is opened by driving the rebar optimization application 34 installed in the storage device 32, through the monitor 22, and the monitor 22. The reinforcing table, assembly drawing, work process drawing, and the like outputted through the printer 24 are output.

In addition, the storage device 32 provided in the main computer 30 is provided with the rebar optimization application 34. At this time, the reinforcing bar optimization application 34 inputs all kinds of reinforcing bar data produced on the market into a database and combines and calculates the input bar based on the databased reinforcing bar data to obtain an optimized assembly drawing and work flow chart. It is a program that produces. In addition, the reinforcing bar optimization application 34 stores the input reinforcing bar data by the thickness (diameter) of the reinforcing bar database, the reinforcing table (Fig. 18), assembly drawing (Fig. 19), work process drawing (Fig. 20) , Create a price calculation table (Fig. 21) and save and output.

The database 40 stores the rebar data input by the rebar optimization application 34 as a database and stores the rebar table (FIG. 18), assembly diagram (FIG. 19), work process diagram (FIG. 20), and price. It is an auxiliary storage device for storing the calculation table (Fig. 21) and the like. In this case, the database 40 may use a storage device of a server computer (not shown) connected to the main computer 30 by a network.

The rebar cutting device 50 is connected to the main computer 30 through a communication network, and is a device for automatically or semi-automatically cutting or bending the rebar by the rebar optimization application 34 installed in the main computer 30. .

The user can automatically or semi-automatically cut or bend the reinforcing bar by instructing the rebar cutting device 50 connected to the main computer 30 through the rebar optimization application 34 through a communication network. In addition, the user outputs the rebar table (FIG. 18), assembly drawing (FIG. 19), work process drawing (FIG. 20), price calculation table (FIG. 21), and the like through the output device 20 while viewing the drawings. Run, cut or bend.

2 is an overall flowchart illustrating a method for rebar optimization service according to the present invention.

First, the rebar optimization service program that inputs reinforcing bar data, stores the database by item, and combines and calculates the reinforcing bar data based on the stored reinforcing bar data to calculate an optimized rebar assembly and work flow chart. It is installed in the storage device of the PC (step S10).

Then, when the rebar optimization service program is driven, the rebar optimization service window window 100 is opened (steps S12 to S10).

Next, a work process room is created in the work process window window 120 of the rebar optimization service window window 100 (step S16).

Next, when the reinforcing bar to be input to the work process room is selected in the rebar selection window 130 (step S18), the data input window 230 of FIG. 12 is opened.

Then, the data related to the reinforcing bar is input to the data input window 230 (step S20).

Then, the reinforcing bar data input to the data input window 230 is registered in the work process room and the reinforcing bar window 140 (step S22).

Then, it is determined whether to modify the reinforcing bar data input to the work process room, and if it is desired to correct the reinforcing bar data, the process proceeds to the next step (step S26), and if it is not desired to proceed to step S34. (Step S24).

Then, if you want to modify the reinforcement data in the step (S26), copy the modified reinforcement data and then modify (step S26). At this time, the correction of the reinforcing bar data automatically modifies the dimension or selects an option based on the data of the inputted design drawing (earthwork).

Next, the optimization option menu is selected in the menu window 110 to organize and store the reinforcing bar data suitable for the optimization operation (step S28). If the optimization option menu is selected, the optimization option window 150 of FIG. 16 opens. Select and enter the target to be optimized, the rebar to be used, the design or change value, and the optimization precision.

Next, an optimization operation is performed (steps S28 to S30).

In this case, when the reinforcing data is input through the reinforcing bar data input menu of the rebar optimization service window window, the optimization calculation method cuts the input reinforcing bar data based on the reinforcing bar data stored in the work room, and then circulates the pieces of each bar. By combining one by one and the number of pieces, the lower loss rate for each basic reinforcing bar is selected and optimized for the total length of the reinforcing bar.
Then, the modified rebar data is registered in the work process room (step S32).

Next, the corresponding item (rebar table, assembly diagram, result) is selected in the output window window 150 (step S34).

Then, calculate the data to output to the screen. The number of pages, output coordinates, etc. are stored in a database (not shown).

Then, the screen is output according to the selected item (rebar table, assembly diagram, result) (step S36).

Then, the content output on the screen is printed (step S38), or the results output on the screen are output to a file (step S40), or the cost is calculated by calculating the price according to the optimization result (step S42). .

3 is a flowchart illustrating a method of inputting reinforcing bar data in FIG. 2.

Referring to FIG. 3, the input is first accepted (step S100).

Then, if the entered value is a command for work process management, go to step S104; otherwise, go to step S126 (step S102).

Next, in step S104, if the input value is a command to create a work process room, the process proceeds to step S106, where the room is named (step S106), and the room classification according to the construction period is specified (step S108). If not, go to step S110.

Then, in step S110, if the input value is a command to modify the name of the work process room, the process goes to step S112, otherwise, the process goes to step S114 (step S110).

Then, in the step S112, the correction window is opened to accept the correction.                     

Then, in step S114, if the inputted value is a command to delete the work process room, the process proceeds to step S116 and the room is deleted, otherwise, the process goes to step S118 (step S114).

Then, in step S118, if the input value is a command to copy the work process room, the process proceeds to step S120 to copy the room, and otherwise, to step S122 (step S118).

Then, in step S122, if the inputted value is a command to paste the work process room, the process proceeds to step S124 and the room is pasted, otherwise, the process returns to step S102 (step S122).

Then, if the value entered in step S126 is a command for work process reinforcement management, go to the next step S128, otherwise return to the step S100 (step S126).

Next, in step S128, it is classified into which work process room to enter the rebar, and then the process proceeds to the next step S130.

Next, in step S130, an input window is generated and ready to accept an input, and then the process proceeds to the next step S132.

Next, in step S132, after inputting the prepared item in the input window, the process proceeds to the next step S134.

Then, in step S134, if the prepared item is not entered in the input window or if there is a problem, the process returns to step S132 and inputs the prepared item again in the input window, and if the item is entered and there is no problem, the next item is entered. Proceed to step S136.

Next, in step S136, it is checked whether there is a join in the rebar. If there is a join in the rebar, the process proceeds to the next step (S138), and if there is no join in the rebar, the process proceeds to a step (S142).

Then, in step S138, the join is automatically cut to the default value, and then the flow goes to the next step S140.

Then, in step S140, the user adjusts and processes the length processed by default, and then proceeds to the next step S142.

Then, in step S142, the elements of the input rebar are combined and added to the existing data, and then the flow proceeds to the next step S144.

Then, in step S144, the screen output is updated again with the added data, and then the flow goes to the next step S146.

Next, in step S146, the data added to the reinforcement window window 140 is inserted, and then the process proceeds to the next step S148.

Next, in step S148, the work process room is again sorted and rechecked, and then the process proceeds to the next step S150.

Next, in step S150, the data of the reworked room is tabulated and stored, and then the process proceeds to the next step S152.

Next, in step S152, it is checked whether all items have been entered in the input window. If the prepared item is not input in the input window or there is a problem, the process returns to step S132 and inputs the prepared item in the input window again.

Next, in step S154, it is checked whether there are more design values. If there are remaining design values, the process returns to step S132 and the input is repeatedly processed. If there are no remaining design values, the process proceeds to the next step S156.

Next, in step S156, the data that has been worked with the database is transmitted.

4 is a flowchart illustrating a method of optimizing a database by rebar data in FIG. 2.

Referring to FIG. 4, first, the input value is stored in an arbitrary memory (step S200), and then, the processing proceeds to the next step S202.

Then, in step S202, the bars are sorted and organized in units of diameter, and then the flow proceeds to the next step S204.

Then, in step S204, if the cleanup is completed, the process proceeds to the next step S206, and if there is an input value that is not yet cleared, the process returns to the step S202 and repeats again.

Next, in step S206, the rebar is classified into the generated work process room, and then the process proceeds to the next step S208.

Then, in step S208, if the classification is finished, the process proceeds to the next step S210, and if the classification of the work process room is not finished, the process returns to the step S206 and repeats again.

Next, in step S210, the optimization option is selected, and then, the processing proceeds to the next step (any one of S212 to S216).

Next, in step S212, the available rebar length is selected, and the flow advances to the next step S218.

Next, in step S214, after selecting the work process room where the optimization is performed, the process proceeds to the next step S218.

Next, in step S216, the optimization rate (speed) is selected, and then, the flow proceeds to the next step S218.

Then, in step S218, the database is created for the optimization process, and then the process goes to the next step S220.

Next, in step S220, the created database is transmitted to the optimizer.

5 is a flowchart illustrating a method of optimizing reinforcing bar data in FIG. 2.

Referring to FIG. 5, the option setting is first read and set from the received reinforcing bar data (step S300), and then the process proceeds to the next step (S302).

Next, in step S302, the rebar data is read in units of diameters, and the flow advances to the next step S304.

Next, in step S304, the rebar data is sorted by length so as to be suitable for the substitution mode, the optimization speed is increased, and the flow proceeds to the next step S306.

Next, in step S306, the optimization option for the substitution mode is specified, and the flow advances to the next step S308.

Then, in step S308, after performing the substitution mode optimization, the process proceeds to the next step S310.

Next, in step S310, it is determined whether the result of the loss is smaller than that of the previous result. If the loss is equal to or greater than the existing result, the process proceeds to the next step S312, and if the loss is smaller, the process proceeds to the step S314.

Next, in step S312, it is determined whether the substitution mode optimization option has been performed. If the substitution mode optimization option has been performed, the process returns to step S306. If the optimization option has not been performed, the process proceeds to the next step S310.

Then, in step S314, the result of the substitution mode is stored and then the flow returns to step S312.

Next, in step S316, the data is sorted by length so as to be suitable for the combination mode, and the optimization speed is increased, and then the process proceeds to the next step S318.

Next, in step S318, the optimization option of the combination mode is designated, and then, the processing proceeds to the next step S320.

Next, in step S320, the optimization of the combination mode is performed, and then, the processing proceeds to the next step S322.

Next, in step S322, it is determined whether the result of the loss is smaller than that of the previous result. If the loss is equal to or greater than the existing result, the process proceeds to the next step S326, and if the loss is smaller, the process proceeds to the step S324.

Next, in step S324, the result of the combination mode is stored, and the flow proceeds to step S326.

Next, in step S326, it is determined whether the combined mode optimization option has been performed. If the combined mode optimization option has been performed, the process returns to step S318. If the optimization option has not been performed, the process proceeds to the next step S326.

Next, in step S326, the loss of the substitution mode and the combination mode is selected, and a better result is selected and stored, and then the flow proceeds to the next step S328.

Next, in step S328, it is determined whether there is data of reinforcing bars having different diameters. If reinforcing bar data of another diameter remains, the process returns to step S302 and the operation is repeated. If not, the program ends.

6 is a flowchart illustrating a method of outputting a screen in FIG. 2.

Referring to FIG. 6, first, data is modified and created according to each output (step S400).

After step S400, the process proceeds to either step S402 or step S406, S408, or S410.

Here, in step S402, the estimated price is calculated and calculated based on the optimization data, and then the process proceeds to the next step S404.

Next, in step S404, the calculated price is output.

On the other hand, in the step (S406) after generating and preparing a memory, variable to output the reinforcing bar table on the screen, and proceeds to the next step (S412).

Then, in step S412, after loading data related to the reinforcing table from the database, the process proceeds to the next step S418.

Next, in step S418, the rebar table is output on the screen according to each work process unit.

Then, in step S408, after generating and preparing a memory and a variable to output the assembly diagram on the screen, the process proceeds to the next step S414.

Next, in step S414, the data related to the assembly drawing is loaded from the database, and the process proceeds to the next step S420.

Next, in step S420, the assembly diagram is output to the screen according to each work process unit.

In addition, in step S410, after generating and preparing a memory and a variable to output the process diagram on the screen, the process proceeds to the next step S416.

Then, in step S416, after loading data related to the process chart from the database, the process proceeds to the next step S422.

Next, in step S422, the result of the optimization performed in the database is input, the results are sorted by each dimension, and the process proceeds to the next step S424.

Next, in step S424, the number corresponding to each dimension is obtained, and then the flow goes to the next step S426.

Next, in step S426, the rebar flow chart and a table are drawn on the screen.                     

7 is a diagram illustrating a screen of a rebar optimization service window window 100 according to the present invention.

As shown in FIG. 7, the rebar optimization service window window 100 screen includes a menu window 110, a work process window 120, a rebar selection window window 130, a rebar window window 140, and an output window. It includes a window 150.

8A to 8E are views illustrating the menu window 110 screen of FIG. 8.

As shown in FIG. 8A, the file menu of the menu window 110 includes a 'new file ( N )' menu for creating a new file, an 'open ( O )' menu for opening an existing file, and an existing open file. "then opening (C) 'menu, and only the" Save (S) "menu for storing the job files, and menu" Save (a) as', selected jakeopbang that the Save as Save the opening by attaching the trap in 'Save Selected Room' menu, 'Print ( P )' menu to print out the results, 'Print Preview ( V )' menu to pre-print the screen before printing, and 'Print' to set printing options Setup ( R ) 'menu and the' end ( X ) 'menu to end the program.

As shown in FIG. 8B, the changed value menu of the menu window 110 includes a 'copy all design values to the changed value (C)' menu, which makes the changed value the same as the design, and compares the design value and the changed value with only other items. It includes a 'Copy Only Items Not Changed' menu (V) for copying changes, and a 'Delete Changes ( D )' menu for deleting all existing changes.

As shown in FIG. 8C, the optimization menu of the menu window 110 includes an 'optimization option ( L )' menu which opens a dialog box for selecting an option during optimization, and an 'optimization operation execution ( P )' for performing optimization. Include a menu.

As shown in FIG. 8D, the setting menu of the menu window 110 includes a 'frequent rebar window' menu for opening a tool for selecting and arranging rebars frequently used when inputting a rebar shape, and rebars displayed on the entire screen. Rebar image / line view mode to select the output of image as line or image, Design view of the changed value separately to display at one time on the output screen, and Rebar window 'Find Assembly ( F )' menu to search by drawing name when there are a lot of rebars, 'Font Settings' menu to change the font displayed on the screen, and 'Preferences' to set margins, print colors, etc. Include a menu.

As shown in FIG. 8E, the basic work tool of the menu window 110 includes a 'Calendar ( C )' menu showing a calendar, a 'Schedule Note ( N )' menu that can manage a schedule on a weekly basis, and a menu. It includes an 'OMP file viewer' menu for reading only the results, a 'view analysis chart' menu for analyzing the results at a usage rate, and a 'price list' menu for outputting an order table for the costs required for the results.

FIG. 9 is a diagram for describing a method of creating a work process directory in the work process window window 120 of FIG. 7.

In the selection name menu window of the work process window 120, as shown in FIG. 9, a 'create room' menu for creating a work process directory (or 'work process room'), and ''Prevent' menu, the 'Rename' menu to rename the created process room, the 'Copy ( C )' menu to copy the file, the 'Paste' ( P ) menu to paste the file, and It includes a 'Save Selected Room' menu to save the room.

10A and 10B illustrate an example of creating a work process directory of FIG. 9.

First, referring to FIG. 10A, a directory “construction” for creating the work process directory (hereinafter, referred to as a “construction directory”) is created in the work process window window 120. The construction directory is a directory on which work is based and is a directory which cannot be deleted by a user. In FIG. 10A, a directory called 'retaining wall' is a directory created by a user in the construction directory.

Similarly, referring to FIG. 10B, an example of creating a directory named 'pier' and a 'top plate' in the construction directory, and then showing subdirectories '1' and '2' in the bridge directory. In this way, a plurality of subdirectories having a small classification can be created in an upper directory having a large classification.

In this way, the user may create a directory for each process and then input data of rebars to be used for each directory.

FIG. 11 is a diagram illustrating a rebar selection window window 130 screen of FIG. 7.

The rebar selection window window 130 includes a plurality of rebar icons each having rebar data input to the work process directory. As illustrated in FIG. 11, the plurality of rebar icons are subdivided according to the types of rebars such as straight line, connecting straight line, L type, C type, LR type and dish type.

12 is a diagram illustrating a screen of a reinforcing bar data input window 230 of a reinforcing bar icon provided in the bar selection window window 130 of FIG. 11.

First, as shown in FIG. 12, the reinforcing bar data input window 230 includes a reinforcing bar window 231 showing the reinforcing bars input in each work process, and a reinforcing bar type selecting window 232 for selecting the reinforcing bar type. And a reinforcing bar thickness selection window 233 for selecting a bar thickness, a reinforcing bar data input box 234 for inputting reinforcing bar data, and a reinforcing bar cutting window window 235 indicating a length to be cut and a shape to be processed. And, an automatic cutting selection button 236 for selecting automatic cutting, a joint number display window 237 for displaying the number of joints, a rebar cutting data input box 238 for inputting rebar cutting data, a selection button 239a, and And a cancel button 239b. Here, the reinforcing bar data entry field 234 includes items such as a name of the bar drawing (Name), the length of each element (a, b), the total number of the bar (N), and the length of joining when cutting the bar (Join). Include.

A method of inputting basic data into the rebar data input window 230 is as follows.

First, the rebar type and the thickness of the reinforcing bar are selected in the rebar type selection window 232 and the rebar thickness selection window 233.

Next, the name is entered in the rebar drawing name item of the reinforcing bar data input box 234 and hit enter. At this time, the Enter key moves the focus to the next item.

Next, enter the lengths (a, b) of the items that fit your figure.

Then enter the total number (N).                     

Finally, enter the length of the join, if there is a join (see the section on entering joins).

FIG. 13 is an explanatory diagram for describing a method of inputting reinforcing bars divided in the reinforcing bar data input window 230 of FIG. 12.

Referring to FIG. 13, when the joint length when reinforcing bars is input into the reinforcing bar data input box 234, an assembly diagram of reinforcing bars automatically appears in the reinforcing bar window 231. When the reinforcing bar divided into the rebar cutting data input box 238 is input, the ratio of each element is displayed in the rebar cutting window 235 and the number of tightenings is displayed in the joint number display window 237. Then, press the auto crop button 236.

14 and 15 illustrate screens in which rebar data input to a work process directory is displayed in a rebar window 140 and an output window window 150 of the rebar optimization service window window 100.

As shown in the drawing, when the reinforcing bar data is input to the work process directory, the assembly diagram of the reinforcing bar input to the rebar window window 140 of the rebar optimization service window window 100 appears, and the output window window 150 According to each item, assembly drawing, work flow chart and price calculation table are displayed.

Meanwhile, a menu window (not shown) appears when a right mouse button is pressed on the rebar to which the command is to be applied in the rebar window window 150. In this case, the menu window includes a menu such as changing the shape of the reinforcing bar, modifying the bar, and deleting the bar.

FIG. 16 is a diagram illustrating a screen of an optimization option window 250 activated by selection of an optimization menu in the menu window 110 of FIG. 8C.

As illustrated in FIG. 16, the optimization option window 250 includes a target selection window 251 to be optimized, a select all button 252, a select reverse button 253, a deselect button 254, and a target selector ( 255), the rebar selection window 256 to be used, the select all button 257, the basic selection button 258, the optimization precision display unit 259, the execute button 260, the cancel button 261, the save button 262 It is configured to include.

17 is a diagram illustrating an optimization execution guide window 270 screen indicating that an optimization operation is being executed.

As illustrated in FIG. 17, the guide window 270 during the optimization operation includes a progress display unit 271, a search display unit 272, a quantity display unit 273, and a minimum button 274.

FIG. 18 is a diagram illustrating an output window screen 150a of rebar table items in the output window window 150 of FIG. 7.

As shown in the drawing, the reinforcing bar table shows data values of the reinforcing bars according to the type of reinforcing bars. The reinforcing bar table includes the diameter (thickness), length, number, total length, unit weight, and gross weight of the reinforcing bar.

FIG. 19 is a view illustrating an output window screen 150b of an assembly drawing item in the output window window 150 of FIG. 7.

The method of designing the assembly diagram of the rebar is as follows.

First, classify the complexity of the rebar.                     

Next, draw the shape of the rebar as a simple picture (line) and save it as a BMP file. At this time, the drawing method indicates what index (eg, radius, elements a, b, items of the same length, etc.) of each element length represents.

Then, the BMP file format is encrypted and converted into a unique file.

The file (assembly diagram file) is then stored in the designated workflow.

Then, the file stored in the work process room is read, the mark is interpreted and printed on a screen or a printer.

On the other hand, since the index and each element of the figure is managed separately when outputting the file can be output quickly and easily.

20 is a view showing an output window screen 150c of a result item in the output window window 150 of FIG.

The method of designing a work flow diagram of the rebar is as follows.

First, the result of performing an optimization operation (for example, the length of the rebar, the index of the drawing used for the rebar, the number, etc.) is retrieved.

Next, the bars are classified according to their diameters.

Then, sort by length for each diameter. For example, they are sorted in ascending order (6m, 7m, ..., 12m).

Next, find the same item in the bar used for each meter, omit it, and increase the number.                     

Then, find and omit duplicates of the drawings (items) used per bar and increase the number.

Next, calculate the total amount of used rebar and the loss rate per current diameter.

Then, the obtained chart is repeatedly outputted until all diameters of each diameter are over.

Next, information on the total usage and loss rate are output.

The work flow chart allows for quick and easy work because the length of the rebar is to be cut and the shape to be processed is output together on one page. The workflow shows how to cut and bend the rebar. Therefore, the user only needs to cut the reinforcing bar for the meter to the dimension shown in the diagram. Then, the processing may be performed by looking at the drawings on the side drawings and the assembly drawings.

Finally, FIG. 21 is a diagram illustrating a screen of a price calculation table (order table) activated by selection of a price calculation table menu in the menu window 110 of FIG. 8E.

The price calculation table calculates the rebar used in the work orderable at a price that is current. As shown in Fig. 21, the length of use and the price of the reinforcing bar for each diameter are output. It also includes a chart that compares the total cost with the base surcharge.

As described above, the present invention first inputs the reinforcement degree which is the first step of reinforced concrete construction. There are about 50 kinds of rebar used in the current construction. If you draw per bar shape and type it, you will have to draw the same or similar shapes. So you can database the 50 types of reinforcement mentioned above in advance and then enter the reinforcing bar quickly if the user puts on each element in its basic shape. In addition, duplicated elements are not inputted according to their shape in advance so that faster input is possible.

Also, for example, reinforcing bars larger than 10m and 12m use several reinforcing bars as one object. The user can reduce the loss by simulating the number of meters of the reinforcing bar using the rebar optimization application 34, the loss is small. At this time, it supports inputting a script per lie such as Excel, and can be input as arithmetic operation.

Long constructions and large constructions can create a process room (or process directory) to work on a work schedule according to the work period and place reinforcing bars in the desired process.

In addition, when a user wants to make a modification in the present design by adding a change value function, the original on the original design is preserved in the design value, and the user can change the part that he / she wants to change and put this data in the change value. At this time, the optimization is selected from the design value and the change value.

Since the change is much the same as the design, you can basically copy the design work to create a default change. In addition, by comparing the design value with the change value, only the portion that is not deformed can be selectively copied.

Reinforcing bar data information input as in the present invention can see the reinforcing bar input so far in the rebar window. In addition, whenever one element is input, the rebar table (FIG. 18) and the assembly diagram (FIG. 19) are updated.

The input reinforcing data information is databaseized and sent to the rebar optimization process. Since the reinforcing bars are classified and used in the field, the database work of the present invention is also classified by the thickness of the reinforcing bars. The data thus classified is again classified into items of the work process room.

The rebar optimization process receives the data summarized above and finds a case where the loss rate is the smallest and organizes the information. First, the information received is sorted by length.

Here, the optimization method uses two methods of substitution mode and combination mode.

Using these two methods separately, we adopt a better algorithm. This optimized data is again accepted by the main process and cleaned up. Then, the information optimized for the output is transformed for each output window. At this time, a basic reinforcing table (rebar table with construction drawings) (FIG. 19) is made, and a rebar assembly drawing (rebar shape and length of each element, etc.) (FIG. 20) is generated. Then, finally, a work flow chart (FIG. 21) is output.

The work flow chart shows how many meters should be cut and how many meters should be cut from the drawings. In addition, in order to bend not only the cutting process, the drawing is placed right next to the work flow chart so that one operation can be performed at a time.

Therefore, the present invention can be easily and quickly rebar work, reducing the waste of the rebar is discarded by reducing the rebar loss.

Preferred embodiments of the present invention as described above are disclosed for purposes of illustration, and those skilled in the art will be able to make various modifications, modifications, additions, etc. within the spirit and scope of the present invention, such modifications and the like belong to the following claims You will have to look.

As described above, according to the recording medium recording the rebar work process optimization service according to the present invention and a method and a computer program for the method, the data processing the reinforcing bar reinforcement process database by computer program By combining and calculating all the reinforcing bars input as a standard, it is possible to produce an optimized work flow chart.

In addition, there is an advantage that anyone can easily design the rebar work flow chart with a computer program.

In addition, various optimization algorithms can be searched simultaneously to extract optimal results in a short time.

In addition, all kinds of rebars can be selected and applied, and rebars can be selected and applied for each meter.

In addition, by processing the reinforcement using the reinforcement table, the assembly diagram and the work flow chart, etc., which are databased by the rebar optimization program, it is possible to lower the loss rate of the reinforcement and to reduce the labor cost.                     

In addition, it is possible to lower the loss rate of the rebar as the number of items and the number of used rebars is maintained because the loss ratio near the optimum is maintained by the combination method of all quantities rather than the optimization method per one bar.

In addition, it is possible to automate the rebar processing operation by automatically controlling the device for cutting the rebar by the rebar data databased by the rebar optimization program.

Claims (61)

delete In the rebar work process optimization service method, (a) Drives the rebar optimization service program that calculates the optimized rebar assembly and work flow diagram by combining and calculating the input reinforcement data by item database and combining and calculating the input reinforcement data based on the stored reinforcement data. Making a step; (b) generating a rebar optimization service window window when the rebar optimization service program is driven; (c) Selecting a work process room creation menu in the rebar optimization service window creates a work process room, stores reinforcing data by item in the work process room, and generates a reinforcing table representing the stored reinforcement data by item. Steps; (d) When reinforcing bar data is input through the reinforcing bar data input menu of the rebar optimization service window window, the input bar data is cut based on the bar data stored in the work process room, and then the pieces of each bar are circulated one by one. Optimizing the total reinforcement length by selecting a method in which the loss rate per base reinforcing bar length is low by combining the number of pieces per piece; (e) classifying the reinforcing bar data performed by the optimization operation into complexity, displaying the shape of the bar as a simple picture, storing it as a BMP file, encrypting the BMP file format, converting the file into a unique file, and Storing the BMP file in a designated work process room, reading the BMP file stored in the work process room, interpreting a mark, and outputting the BMP file to a screen or a printer to design a rebar assembly diagram; (f) calling up the result value of the reinforcing bar data which has performed the optimization operation, classifying the reinforcing bar according to the diameter according to the result of the reinforcing bar data, sorting the sorted bar according to the length per diameter, and The same items are omitted from the reinforcing bars and the number is increased, the overlapping items of the reinforcing bars are omitted, the number is increased, and the total amount and the loss ratio of the used bars per diameter are calculated. Repeating until then outputting information on the total use and the loss rate to design a work flow diagram; (g) calculating a price of the rebar required by the work flow chart by using a price calculation table; And and (h) storing the calculated rebar assembly drawing and work flow chart and outputting at least one of a file, a monitor screen, and a printer. delete The method of claim 2, Reinforcing bar work process optimization service method, characterized in that the reinforcing bar data stored in the work process room is classified and stored in units of the diameter of the rebar. delete delete The method of claim 2, wherein the rebar work flow optimization service method is: Copying and changing reinforcing bar data when changing reinforcing bar data stored in the work process room; Selecting one of the reinforcement data and the changed reinforcement data stored in the work process room by an optimization operation; And And storing newly one reinforcing bar data selected by the optimization operation in the work process room. The optimization operation is: A first step of organizing the reinforcing bar data by diameter to be suitable for a substitution mode; A second step of specifying an optimization option for the substitution mode after the step; A third step of performing substitution mode optimization after the step; A fourth result of temporarily storing the result value when the loss is small compared to the existing result value, and repeating the second and third steps until the loss is smaller than the existing result value. Steps; A fifth step of organizing the reinforcing bar data by diameter to be suitable for a combined mode; A sixth step of specifying an optimization option for the combined mode after the step; A seventh step of performing combined mode optimization after said step; An eighth step of repeating the sixth and seventh steps until the result value of the combination mode optimization is smaller than the existing result value and the result value is temporarily stored; Steps; A ninth step of comparing the result value of the substitution mode with the result value of the combination mode to select and store a value having a small loss; And Rebar work process optimization service method characterized in that it comprises a ;; if there is reinforcement data of different diameters; tenth step of repeating the first to ninth step. delete delete The method of claim 2, The work process room is a rebar work process optimization service method, characterized in that it is possible to create, rename, delete, copy, paste the room. The method of claim 2, wherein the rebar work flow optimization service method is: Automatically cutting the join to a default value when there is a join in the reinforcing bar while inputting the reinforcing bar data into the work process room; Adding the input reinforcing bar data and reinforcing bar data stored in the work room; Updating the screen output again by the added rebar data; And And storing the added reinforcing bar data in a newly created work process room. The method of claim 2, wherein the rebar optimization service window window is: A menu window having a menu of various functions; A work process window window for making the work process room; A rebar selection window window having a plurality of rebar data to select rebar data to be input to the work process room; Reinforcing window windows each showing the assembly diagram of the reinforcing bar data input to the work process room; And Reinforcing work flow chart optimization service method comprising a; window for displaying the assembly diagram, work flow diagram, price calculation table, reinforcement table by the item selection. The method of claim 12, wherein the menu window is: 'New File ( N )' menu to create a new file; 'Open ( O )' menu to open an existing file; 'Open after' menu to trap existing open files; 'Save ( S )' menu to save the work file; Save (A) As "menu to save under a different name; 'Save selected rooms only' menu to save only the selected room; 'Print ( P )' menu to print results; A 'print preview ( V )' menu for previewing the printout screen; 'Print Setup ( R )' menu for setting options related to printing; And Rebar work process optimization service method comprising a file menu with a 'end ( X )' menu to end the program. The method of claim 13, wherein the menu window is: 'Copy All Design Values to Changes' menu to create the same change as the design; 'Copy Only Items Not Changed' menu (V), which compares the design and the changed values and copies only the other items to the changed values; And Rebar work process optimization service method characterized in that it comprises a change value menu having a 'Delete Change Value ( D )' menu to delete all existing changes. The method of claim 14, wherein the menu window is: 'Optimization Options ( L )' menu to open a dialog box from which you can select options during optimization; And Rebar work process optimization service method characterized in that it comprises an optimization menu having an 'optimization operation execution ( P )' menu to perform the optimization. The method of claim 15, wherein the menu window: Frequently used rebar window that opens a tool for selecting and organizing rebars frequently used when entering rebar shape; 'Rebar image / line view mode' menu that selects the rebar image displayed on the entire screen as a line or an image; 'View Design Value Changes' menu, which selects to display the design value changes at once in the output screen; 'Find Assembly ( F )' menu to search by drawing name when there are many bars in the rebar window; 'Font Settings' menu to change the font displayed on the screen; And Rebar work process optimization service method characterized in that it comprises a setting menu with a 'environmental settings' menu to set the margin, printout color and the like. The method of claim 16, wherein the menu window: 'Calendar ( C )' menu showing the calendar; On a weekly basis to manage the schedule, week schedule notes (N) 'menu; 'OMP file viewer' menu to read only results; 'Analyze chart view' menu to analyze the results by the usage ratio; And Rebar work process optimization service method comprising a basic work tool menu with a 'price calculation table' menu for outputting the order table for the cost required for the result. 13. The work process window pane of claim 12, wherein: 'Create a room' menu to create the working process room; A 'preventing' menu for erasing the created work process room; A 'name change' menu for changing a name of the created work process room; 'Copy ( C )' menu to copy files; 'Paste ( P )' menu to paste files; And Rebar work process optimization service method characterized in that it comprises a 'save selection room' menu for storing the selection room. The method of claim 12, wherein the reinforcing bar selection window: Rebar work process optimization service method characterized in that it comprises a plurality of reinforcing bar icons each having rebar data input to the work process room. The method of claim 19, The plurality of reinforcing bar icon is a rebar work process optimization service method, characterized in that broken down according to the type of reinforcing bars, such as straight line, connecting straight line, L type, C type, LR type, dish type. The method of claim 20, Rebar work process optimization service method, characterized in that when the reinforcing bar icon is clicked, a reinforcing bar data input window for inputting reinforcing bar data is opened. The method of claim 21, wherein the reinforcing bar data input window: Rebar window window showing the reinforcing bar input in each work process in the drawing; A rebar type selection window for selecting the rebar type; Rebar thickness selection window for selecting the thickness of the reinforcing bar; A reinforcing bar data input box for inputting the reinforcing bar data; Reinforcing bar cutting window showing the length to be cut and the shape to be processed; An auto crop select button for selecting auto crop; Joint number display window for displaying the number of joints; A rebar cutting data input box for inputting rebar cutting data; And Reinforcing work flow diagram optimization service method comprising a; select button and a cancel button. The method of claim 22, The reinforcing bar data field includes reinforcing bar name (Name), length of each element (a, b), total number of reinforcing bars (N), length of joining when cutting the bar (Join) Process Chart Optimization Service Method. 13. The method of claim 12, wherein the reinforcing window window is: If you press the right button of the mouse on the rebar to which the command will be applied, the rebar work process optimization service method, characterized in that the menu window including reinforcing reinforcement, modifying reinforcement, delete reinforcing bar opens. The method of claim 15, The Optimization Options window opened by clicking on the Optimization Options ( L ) menu is: A target selection window for selecting a target to be optimized; Respective buttons for selecting all, inverting and deselecting; An object selection unit for selecting a design value and a change value; Rebar selection window to select rebar to use; Select buttons, each button for basic selection; An optimization precision display unit for displaying the optimization precision; And Reinforcing work flow diagram optimization service method comprising a button for executing, canceling, saving. The method of claim 25, Rebar work process optimization service method further comprises a guide window during optimization indicating that the operation is in progress during the execution of the optimization operation. delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete

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