KR20060011087A - Apparatus for designing a girder of bridge - Google Patents

Abstract

The present invention calculates the girder arrangement information such as the optimal bridge span length and angle of each point and shoe coordinate information on the basis of the specifications information input by the designer and based on the girder in the bridge to automatically perform the arrangement of the girder It relates to an automatic placement device of.

In the bridge according to the present invention, the automatic arrangement of girders is provided with an input unit for setting output conditions of predetermined specification information and designed information related to the girder design, a display unit for displaying and outputting various information input screens and drawing information, and provided from the input unit. Specification processing unit for classifying the specifications information to be suitable for drawing drawing, arithmetic processing unit for calculating the girder arrangement information including the length of the bridge, the angle of each point and the shoe coordinates based on the specifications information processed in the specification processing unit And a drawing processor which generates drawing data in plan and cross-sectional form so as to correspond to the specification information and the girder arrangement information processed by the specification processing unit and the calculation processing unit, and controls the specification processing unit, the calculation processing unit, and the drawing processing unit to be applied from the input unit. Calculation of girder placement information based on the information and output provided from the input unit The girder arrangement information is controlled to be displayed and output as numerical information, as a plan view and a sectional view through the display unit so as to correspond to the case, and when the preset information is changed for the girder arrangement information output through the display unit, It is characterized in that it comprises a control means for controlling to automatically recalculate the optimum girder placement information through a processing unit, arithmetic processing unit and drawing processing unit.

Description

Apparatus for designing a girder of bridge

1 is a cross-sectional view showing a schematic structure of a bridge.

Figure 2 is a block diagram showing the functional separation of the internal configuration of the automatic arrangement of the girder in the bridge according to the invention.

3 is a block diagram illustrating the internal structure of the specification processor 40 shown in FIG.

4 is a diagram illustrating an information table configuration of the girder design information storage unit 70 shown in FIG.

5 is a view for explaining the operation of the automatic arrangement of the girders in the bridge shown in FIG.

FIG. 6 is a view showing an example of an input / output screen provided in the automatic arrangement apparatus of the girder in the bridge shown in FIG.

******* Brief description of the main parts of the drawing *******

10: input unit, 20: display unit,

30: printer, 40: specification processing unit,

50: arithmetic processing unit, 60: drawing processing unit,

70: girder design information storage unit, 80: data memory,

90: control unit.

The present invention calculates the girder arrangement information such as the optimal bridge span length and angle of each point and shoe coordinate information on the basis of the specifications information input by the designer and based on the girder in the bridge to automatically perform the arrangement of the girder It relates to an automatic placement device of.

A bridge is an elevated structure made up of rivers, lakes, straits, bays, canals, or other traffic or structures that can cross over. The upper structure serves as a floor that directly supports vehicles and trains passing through the bridge as a main part of the bridge, and the lower structure is a portion for supporting the upper structure, and transfers load from the upper structure to the ground. It will play a role.

Figure 1 is a cross-sectional view schematically showing the structure of the bridge, as shown in Figure 1, the upper structure is configured in such a way that a plurality of girders (2) are sequentially arranged below a certain distance below the plate-shaped slab (1) The shoe (Shoe: 3) is arranged in the lower end of each end of each girder (2). In addition, the substructure is configured by arranging the pier 4 and the shift 5 for supporting both ends of the girder 2.

Here, the girder 2 is generally configured in a straight line shape, the length of which is fixed. Therefore, when the bridge is produced in a straight line, the girders 2 are arranged and designed by using a conventional placement method.

However, when the bridge is configured to have a planar linear shape such as a curve or a crosoid, in the design stage of the bridge, the arrangement of the girders is a very important factor that determines the life of the bridge. That is, in planar bridges such as curves and cross-sections, the height difference between the girder start point and the girder end point caused by the vertical longitudinal elevation of the bridge, the height difference due to the left and right superelevation slope, and the height change caused by the girder being placed on the slope The girder is to be arranged and designed in consideration of this. In this case, when the girder is disposed incorrectly, the bridge may be twisted over time, such that the life of the bridge is shortened.

In the related art, in consideration of the above matters, the designer directly performs an optimal layout design of the girder through a complicated process for the layout design of the girder. However, the process for carrying out the girder layout is complicated, which may cause designers to make errors and mistakes in planning, as well as the planning time, which results in a delay in bridge design time. do. In addition, considering that various types of arrangements are possible for a single girder arrangement design, there is a problem that this modification takes much time.

Accordingly, the present invention was created in view of the above circumstances, and based on the specifications information for the girder arrangement, the girder arrangement information such as the length of the bridge, the angle of each point, and the shoe coordinates was calculated, and the specification information and the calculated information were calculated. Its technical purpose is to provide an automatic placement device for girders in bridges that are capable of automatically converting and providing girder placement information for current and radial placement of girders.

In order to achieve the above object, the automatic arrangement of girders in a bridge according to the present invention includes an input unit for setting output conditions of predetermined specification information and designed information related to girder design, and for displaying and outputting various information input screens and drawing information. Girder arrangement including the length of the bridge, the angle of each point and the shoe coordinates based on the specification processing unit for classifying and processing the specification information provided from the input unit so as to be suitable for drawing drawings, and the specification information processed by the specification processing unit. A calculation processing unit for calculating information, a drawing processing unit for generating drawing data in plan and cross-sectional views so as to correspond to the specification information and the girder arrangement information processed by the specification processing unit and the calculation processing unit, by controlling the specification processing unit, the calculation processing unit and the drawing processing unit Girder arrangement information is calculated based on the specification information applied from the input unit; The display unit controls to display and output the girder arrangement information as numerical information and plan view and sectional drawing information so as to correspond to the output condition provided from the input unit, and the preset information is changed for the girder arrangement information output through the display unit. If it is characterized in that it comprises a control means for controlling to automatically recalculate the optimum girder placement information through the specification processing unit, the calculation processing unit and the drawing processing unit.

That is, according to the above, the girder layout design in the form desired by the designer is automatically provided based on the girder specifications, thereby minimizing the designer's mistake or the error in the structural plan as the designer manually calculates the information for the girder layout design. As a result, it is possible to design a stable bridge and shorten the design time.

Next, an embodiment according to the present invention will be described.

Figure 2 is a block diagram showing the functional separation of the internal configuration of the automatic arrangement of the girder in the bridge according to the present invention.

In FIG. 2, reference numeral 10 denotes an input unit for inputting various types of information for performing automatic arrangement of the bridge girder according to the present invention, and reference numeral 20 denotes a screen for inputting various types of information related to the arrangement design of the bridge girder and the designed girder arrangement. A display unit for displaying and outputting information in the form of numerical values or drawings, 30 is a printer as recording sheet output means for outputting recording sheet for girder arrangement information. Here, the input unit includes a numeric key and a plurality of girder arrangement related function keys. In addition, the printer 30 may be configured to combine various recording paper output means, such as a plotter, wherein the type of recording paper output means and the output form of the design information, for example, the type of design drawings, through the input unit 10. And output formats.

In FIG. 2, reference numeral 40 denotes a specification processing unit for classifying various specifications information input for automatic girder layout design to be suitable for drawing processing. Here, the specification processor 40 is built-in a program for classifying the specifications information provided through the input unit 10. In addition, the program is provided to enable various types of girder arrangement by changing and setting the coefficient values for a predetermined specification, the basic specification processing block 41 as shown in Figure 3 in accordance with the characteristics of the input specifications information And a general specification processing block 42. That is, the basic specification processing block 41 processes the linear condition information of the bridge such as planar linearity, longitudinal gradient, partial gradient, square of the bridge, coordinates of the bridge, elevation, etc. so as to be suitable for drawing. The general specification processing block 42 draws information about the general specifications of the bridge and the layout of the girder such as the bridge construction, the angle of the point, the clearance of the bridge, the starting point of the bridge, etc. according to the structural plan according to the terrain. Process to suit.

In FIG. 2, reference numeral 50 denotes an arithmetic processing unit for calculating the interval lengths of the bridges and the angles and shoe coordinates of the bridges according to the arrangement types through a predetermined arithmetic processing based on the specification information processed by the specification processing unit 40. . Here, the calculation processing unit 50 performs a predetermined structural analysis on the specifications information and the drawings corresponding to the input information set in the specification processing unit 40 to determine whether the structurally erroneous specification data has been input when setting the girder And a predetermined operation program for determining. This is to impart stability to the girder arrangement design through the automatic arrangement of the bridge girders according to the present invention by driving the program every time the specification information is changed.

Reference numeral 60 denotes a drawing processing unit for converting the specification information provided from the specification processing unit 40 and the calculation processing unit 50 into drawing information in a plan view or cross-sectional form, for example, information in a DXF file format. In addition, the drawing processing unit 60 is provided with a program for converting the drawing information in the DXF file format into the DWG format, which is a general CAD file format, or the PLT format, which is a drawing file format of a plotter. It is configured to enable output in various file formats.

Further, reference numeral 70 is a girder design information storage unit for storing the designed girder arrangement information, 80 is a data memory for storing various processing data processed by the control unit 90 to be described later, 90 is the present invention The control unit for controlling the overall arrangement of the bridge girders according to.

Here, as shown in Figure 4, the girder design information storage unit 70 stores the environmental information such as the bridge installation location, designer, construction date, design cost, etc. for each girder identification code, basic specification information, general specification information The specification information and the girder drawing information determined by the design are stored.

The controller 90 automatically calculates the optimal bridge span length for the girder arrangement, the angle of each point, and the shoe coordinates through the operation processor 40 based on the specification information applied from the input unit 10. In addition to controlling to provide in numerical form through 20), the specifications information processed by the specification processor 40 and the calculation processing unit 50 is provided to the drawing processing unit 60 to convert information on the girder arrangement into drawing information. After that, the girder arrangement information is output through the display unit 20 in the form of a plan view or a sectional view based on the information output condition information applied from the input unit 10. In addition, the control unit 90 gives a predetermined identification code to the girder arrangement information determined design, and controls to store the girder arrangement design information corresponding to the girder identification code in the girder design information storage unit 70.

 Next, the operation of the automatic placement device for the girder in the bridge having the above-described configuration will be described with reference to the flowchart shown in FIG.

First, the space information of the place where the bridge is installed by the designer is provided to the automatic bridge girder arrangement according to the present invention. In this case, the spatial information is applied to the specification processor 40 as the planar linear information for linearly providing the measurement plane linear information for the automatic girder arrangement, that is, the shape of the bridge.

In the above state, when the designer inputs the girder arrangement design request information through the input unit 10 of the automatic girder arrangement according to the present invention, the control unit 90 displays predetermined information input screen information for automatic girder placement. Control to display output through (20). Then, the designer inputs various specifications information values for the desired girder arrangement through the input unit 10 (ST1). At this time, the specifications information input by the designer is based on the basic specifications and terrain related to the linear conditions of the bridge, such as the plane linear, longitudinal gradient, partial gradient, the square of the bridge, the type of bridge, the coordinates of the bridge, elevation It includes general construction values of bridges, girder layout information, etc., including the bridge construction, angle of point, bridge clearance, bridge starting point, etc. according to the structural plan.

In addition, the designer sets the output conditions of the girder arrangement information, for example, the arrangement type of the girder (current reference arrangement / radial arrangement) together with the specification information input through the input unit 10. 6A illustrates an input / output screen for setting an output condition of girder arrangement information, which is composed of an output condition setting item 110 and a result output item 120. Here, the output condition setting item 110, in particular, the girder specification information of "length between the girder end" and "shoe length at the end of the girder" and "minimum distance of the slab end", and "calculation of the girder starting point slope application" / "girder length Layout option information of "End Application Calculation" / "Girder Length Superelevation Application Calculation", "Optimal Automatic Calculation Based on Start Point" / "Shoe Straight Line Based on Start Point" / "Optical Automatic Calculation Based on End Point" Shoe optimum calculation information such as reference shoe straight line placement ", angle setting information such as" right angle to all points "/" same angle as the point of view "/" same point and offset angle "/" apply the same angle deviation ", and" automatic placement of the current standard " And the batch type information of " / " radial type automatic batch ". In addition, the output condition setting item 110 is configured to set the "validation of Excel output" so that the girder arrangement related information can be provided in the form of an Excel file. In addition, the result output item 120 is screen output information provided by the step ST3 to be described later, the specification information and the interval length information for each point of the bridge calculated by the output condition setting item 110 and It is configured to provide the angle information as numerical information.

On the other hand, when the various specifications information and the output condition information on the bridge is input from the input unit 10 of the girder placement device in step ST1, the control unit 90 stores the output condition information in the data memory 80 and the input unit 10 The specification information applied from) is provided to the specification processor 40.

In addition, the specification processor 40 separately stores the input specification information through the basic specification processing block 41 and the general specification processing block 42 so as to be suitable for drawing processing (ST2).

Subsequently, the controller 90 controls to calculate and store girder arrangement information such as the length of the bridge, the angle of each point, and the shoe coordinates, based on the information stored in the specification processor 40 through the operation processor 50. (ST3). In this case, the control unit 90 controls to display the girder arrangement information calculated by the operation processing unit 50 as numerical information through the display unit 20 (the result output item 120 of FIG. 6A).

In addition, the control unit 90 controls the drawing processing unit 60 to combine the information stored in the specification processing unit 40 and the calculation processing unit 50 to generate drawing information in the form of a plan view or a cross-sectional view, for example, DXF file. In addition, (ST4), it is controlled to display the drawing information processed by the drawing processing unit 40 through the display unit 20 (ST5). In this case, the controller 90 converts the girder arrangement information to correspond to the preset output condition information by providing the output condition information stored in the data memory 80 to the drawing processing unit 40, and displays the converted girder arrangement information. 20) it is displayed and output as a drawing. 6B to 6I illustrate various screen examples for providing girder arrangement information in the form of a drawing. 6B to 6E are diagrams showing the girder arrangement form according to the "angle information" setting in FIG. 6A. FIG. 6B is a case where "all points perpendicular" and FIG. 6C is "the same angle as the viewpoint." 6D shows a case of "starting point and an offset angle", and FIG. 6E shows an example of a screen in the case of "the same application of angular deviation". FIG. 6F is a screen according to the "Shoe Optimal Calculation" setting in FIG. 6A, in particular, an output screen at the time of "Point-based optimal automatic calculation". At this time, the start point shoe coordinates and the end point shoe coordinates of the corresponding section are changed. 6G and 6F are girder arrangement screens according to the " girder arrangement type " setting in FIG. 6A, in particular, FIG. 6G shows an output screen at the time of " current standard automatic arrangement ", and FIG. 6F is a " radial automatic arrangement ". The output screen of the city is shown. 6I is a girder arrangement screen in the form of a sectional view according to the " girder arrangement option " setting in FIG. 6A, in particular an output screen when " calculation of starting point gradient application " This applies the spacing to the joint at the beginning or end of the girder due to the slope of the height difference caused by the longitudinal and superelevation slopes during the <automatic placement> or <automatic calculation>.

On the other hand, the control unit 90 through the input unit 10 in the state of outputting the girder arrangement information through the display unit 20 to correspond to the output conditions set by the designer as described above (eg, girder specification information) Or whether the predetermined specification information or the output condition information is changed through the input unit 10, the control unit 90 determines whether the change setting of the output condition information (for example, the radial automatic arrangement) is performed. The specification processor 40 is updated or the output condition information stored in the data memory 80 is changed based on the specification information applied from (10) (ST7). Then, the process after the above-described step ST3 is repeated. That is, the designer can arbitrarily change and set the girder specification information and receive a girder layout drawing corresponding thereto. In addition, the designer can be provided by variously modifying the girder arrangement form based on the preset specification information.

In addition, the controller 90 checks whether the girder arrangement determination information is applied through the input unit 10 when the information is not changed in step ST6 (ST8), and when the predetermined girder arrangement determination information is applied, arranges the girder. A predetermined identification code is assigned to the information, and the girder design information is stored in the specification information, the girder arrangement information, and the drawing information stored in the specification processor 40, the calculation processor 50, and the drawing processor 60 for the girder identification code. Control to store in the unit 70 (ST9). At this time, the girder design information storage unit 70 is additionally stored in the environment information, such as the design position, design date, designer of the bridge provided from the input unit 10 by the designer. This is to be used as a reference for future girder layout design.

In addition, the controller 90 controls to output the girder arrangement information designed based on the recording sheet output request information applied from the input unit 10 through the printer 30.

That is, according to the above embodiment, by automatically calculating the optimal bridge spacing distance and girder arrangement information such as angles and shoe coordinates based on the girder-related specification information, the numerical information or the plan view and the cross-sectional view are provided. It is not only possible to easily perform the optimum layout design of the girder according to the change of the specification information and the layout form, but also to make sure the designer can check the design details of the bridge more easily by confirming the layout of the girder through the drawing information. It becomes possible.

In addition, the girder layout design in the form desired by the designer is automatically provided based on the girder specifications, thereby minimizing the designer's mistakes or calculation errors as the designer manually calculates the information for the girder layout design. This enables stable bridge design and shortens the design time.

In addition, the present invention is not limited to the above embodiments, and various modifications can be made without departing from the technical spirit of the present invention.

As described above, according to the present invention, the girder arrangement design in the form desired by the designer is automatically provided based on the girder specifications, so that the designer calculates the information for the girder arrangement design by hand, This minimizes errors, resulting in stable bridge design as well as shortening the design time.

Claims (2)

An input unit for setting output specifications of predetermined specification information and designed information related to the girder design, A display unit for displaying and outputting various information input screens and drawing information; Specification processing unit for classifying the specifications information provided from the input unit to be suitable for drawing drawing, An arithmetic processing unit for calculating girder arrangement information including lengths of bridges, angles of respective points, and shoe coordinates based on the specification information processed by the specification processing unit; A drawing processing unit which generates drawing data in plan and cross-sectional form so as to correspond to the specification information and the girder arrangement information processed by the specification processing unit and the calculation processing unit; The girder arrangement information is calculated based on the specification information applied from the input unit by controlling the specification processing unit, the arithmetic processing unit, and the drawing processing unit, and the girder arrangement information is converted into numerical information, a plan view, and a sectional view through the display unit so as to correspond to an output condition provided from the input unit. In addition to controlling the display output in the form of drawing information, when the preset information is changed for the girder arrangement information output through the display unit, the optimum girder arrangement information is automatically reset through the specification processor, the calculation processor, and the drawing processor. Automatic arrangement of girders in the bridge, characterized in that it comprises a control means for controlling to calculate. The method of claim 1, The control means includes girder specification information including "distance between ends of girder" and "shoe length information at the end of girder" and batch type information including "current reference automatic placement" and "radial automatic placement", and "right angle of every point". Angle information including "and" equal to start point "," start and offset angle "," apply same angle deviation "," automatic calculation of starting point reference "and" linear alignment of starting point shoe "," optimal automatic calculation based on end point Shoe optimum calculation information including "," Shoe straight line reference to end point "and girder placement option information including" Calculation of girder starting point slope application "and" Girder length end application calculation "and" Girder length superelevation application calculation " Automatic placement of girders in bridges, characterized in that the control to recalculate the optimum girder placement information in accordance with the change.

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