KR101657638B1 - Apparatus and method for calculating wind load considering topographic factor - Google Patents

Abstract

The present invention relates to an apparatus and a method for calculating a wind load in consideration of a terrain factor. An apparatus for calculating a wind load according to an embodiment of the present invention includes an information collecting unit for collecting position and height information of a plurality of points in a target area; A target area setting unit setting a target point using the position and height information, and setting an area having a predetermined shape and size as a target area around the target point; And a vertex for calculating a vertex height for calculating a wind load applied to the structure by subtracting a height of an earth surface located on a line passing from a vertex of the target area to a point where the structure is located, And a height calculation unit.

Description

[0001] APPARATUS AND METHOD FOR CALCULATING WIND LOAD CONSIDERING TOPOGRAPHIC FACTOR [0002]

The present invention relates to an apparatus and a method for calculating a wind load in consideration of a terrain factor.

The influence of wind in the design of structures is one of the items to be considered. Wind characteristics such as wind velocity or wind direction can be affected by the surrounding topography and may threaten the safety of the structure if the wind speed is accelerated by the surrounding terrain. Therefore, it is required to reflect the change of the wind speed according to the surrounding terrain into the design of the structure.

In order to consider the change of the wind velocity by the terrain, the terrain factor is introduced when calculating the design wind speed. The terrain factor is set to 1.0 for areas that do not affect the wind, such as flat land, but greater than 1.0 for areas that change wind speed, such as mountains, hills, or slopes.

The terrain factor is calculated on the basis of the specified windward and downwind slopes according to the wind direction of the surrounding terrain. However, in the past, the surrounding terrain as a reference for calculating the terrain factor has been subjectively and arbitrarily determined by the designer. As a result, the terrain coefficient calculated by the conventional method does not sufficiently reflect the influence of the terrain on the wind, so that the wind load may be calculated to be too large or small.

It is an object of the present invention to provide a wind load calculation device and method that can quantitatively and reasonably reflect the influence of a terrain on the wind.

An apparatus for calculating a wind load according to an embodiment of the present invention includes an information collecting unit for collecting position and height information of a plurality of points in a target area; A target area setting unit setting a target point using the position and height information, and setting an area having a predetermined shape and size as a target area around the target point; And a vertex for calculating a vertex height for calculating a wind load applied to the structure by subtracting a height of an earth surface located on a line passing from a vertex of the target area to a point where the structure is located, And a height calculation unit.

The information collecting unit may include: an electronic map including position and height information of the plurality of points; And survey data obtained by surveying the plurality of points; The position and height information may be obtained from at least one of the position and height information.

The information collecting unit may include: an electronic map including geographical information on the target area; And survey data obtained by surveying the target area; (DEM) for the target area by using at least one of the digital elevation model and the digital elevation model, and obtain the position and height information from the digital elevation model.

Wherein the target area setting unit sets the target location as a location where the structure is located and sets an area having a predetermined shape and size as a center around the target location as the target area, And a second area having a predetermined shape and size centered on the object point, the method comprising: setting a region having a predetermined shape and size as a first region, setting a highest point in the first region as the object point, The method comprising: setting a target area or an area having a predetermined shape and size around a point where the structure is located as a first area; setting a predetermined shape and size centered on a highest point in the first area; Is set as the second area, and the highest point in the (N-1) th area is set as the target point Settings, and it can set the first N region having a predetermined shape and size with respect to the target point in the target area.

Wherein the vertex height determination unit determines the highest point in the target area as the vertex and the lowest point among the plurality of points on the line passing through the highest point in the target area and the point at which the structure is located; A point having a height corresponding to an optimal one of a plurality of points located on a line passing through a highest point in the target area and a point where the structure is located; A point having a height corresponding to a rank of the highest degree in a frequency distribution of heights of a plurality of points located on a line passing through a highest point in the target area and a point where the structure is located; Or a point having a height corresponding to the lowest rank in the frequency distribution for the height of the plurality of points located on the line passing through the highest point in the target area and the point at which the structure is located can be determined as the surface have.

The vertex height calculation unit may calculate a vertex height using an interpolation method based on at least one of an electronic map including position and height information for a plurality of points in the object area and measurement data obtained by measuring a plurality of points in the object area, Acquiring position and height information of a plurality of points on a line passing through a highest point in the target area and a point on which the structure is located, determining the highest point in the target area as the vertex, The lowest point of the plurality of points located on the line passing through the highest point and the point where the structure is located; A point having a height corresponding to an optimal one of a plurality of points located on a line passing through a highest point in the target area and a point where the structure is located; A point having a height corresponding to a rank of the highest degree in a frequency distribution of heights of a plurality of points located on a line passing through a highest point in the target area and a point where the structure is located; Or a point having a height corresponding to the lowest rank in the frequency distribution for the height of the plurality of points located on the line passing through the highest point in the target area and the point at which the structure is located can be determined as the surface have.

The wind load calculation apparatus may further include a terrain coefficient calculation unit for calculating a terrain coefficient based on the peak height.

A wind load calculation method according to an embodiment of the present invention includes: collecting position and height information of a plurality of points in a target area; Setting a target point using the position and height information, and setting an area having a predetermined shape and size as a target area around the target point; And calculating a vertex height for calculating a wind load applied to the structure by subtracting a height of the ground surface located on a line passing through a vertex of the target area from a height of a vertex of the target area and a point at which the structure is located ; ≪ / RTI >

The collecting of the position and height information may include: an electronic map including position and height information for the plurality of points; And survey data obtained by surveying the plurality of points; And obtaining the position and height information from at least one of the position and height information.

The step of collecting the position and height information may include: generating a digital elevation model for the target area using at least one of an electronic map including geographic information on the target area and survey data obtained by measuring the target area; ; And obtaining the position and height information from the digital elevation model.

Wherein the step of setting the target area comprises: setting a point where the structure is located as the target point, and setting an area having a predetermined shape and size around the target point as the target area; A region having a predetermined shape and size around a point where a structure is located is set as a first region, a highest point in the first region is set as the object point, Setting a second region having a predetermined size and size as the target region or setting a region having a predetermined shape and size around a point where the structure is located as a first region, The process of setting the area having the predetermined shape and size as the second area around the high point is repeated to obtain the N-1 Setting the highest point in the area as the target point and setting the Nth area having the predetermined shape and size as the target area around the target point.

The step of estimating the vertex height includes: determining the highest point in the target area as the vertex; And a plurality of points located on a line passing through the lowest point among the plurality of points located on the line passing through the highest point in the target area and the point where the structure is located, Of a point having the highest frequency in the frequency distribution of the height of a plurality of points located on a line passing through the highest point in the target area and the point where the structure is located, , Or a height corresponding to the lowest rank in the frequency distribution of the height of a plurality of points located on a line passing through the point at which the structure is located and the highest point in the target area And determining a point having the land surface as the ground surface.

Wherein the step of estimating the vertex height comprises: interpolating based on at least one of an electronic map including position and height information for a plurality of points in the object area, and survey data obtained by surveying a plurality of points in the object area; Obtaining position and height information of a plurality of points located on a line passing through a highest point in the target area and a point at which the structure is located; Determining the highest point in the target area as the vertex; And a plurality of points located on a line passing through the lowest point among the plurality of points located on the line passing through the highest point in the target area and the point where the structure is located, Of a point having the highest frequency in the frequency distribution of the height of a plurality of points located on a line passing through the highest point in the target area and the point where the structure is located, , Or a height corresponding to the lowest rank in the frequency distribution of the height of a plurality of points located on a line passing through the point at which the structure is located and the highest point in the target area And determining a point having the land surface as the ground surface.

The wind load calculation method may further include calculating a terrain factor based on the peak height.

The wind load calculation method according to the embodiment of the present invention can be implemented by a computer-executable program and recorded on a computer-readable recording medium.

According to the embodiment of the present invention, the wind load can be calculated by quantitatively and reasonably reflecting the influence of the terrain on the wind.

1 is a block diagram showing a wind load calculation apparatus according to an embodiment of the present invention.
2 is a diagram illustrating an example of an object area set according to an embodiment of the present invention.
3 is a view showing an example of a target region set according to an embodiment of the present invention.
4 is a view showing an example of a target region set according to another embodiment of the present invention.
Fig. 5 is a side view and a downwind side view of the terrain, which is illustratively shown to explain a parameter calculation process according to an embodiment of the present invention.
FIG. 6 is a diagram for explaining a process of calculating an air-side horizontal distance using interpolation according to an embodiment of the present invention.
FIG. 7 is a diagram for explaining a process of calculating a downward-side vertical distance using interpolation according to an embodiment of the present invention.
FIG. 8 is a flowchart illustrating a wind load calculation method according to an embodiment of the present invention.

Other advantages and features of the present invention and methods for accomplishing the same will be apparent from the following detailed description of embodiments thereof taken in conjunction with the accompanying drawings. The present invention may, however, be embodied in many different forms and should not be construed as being limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the concept of the invention to those skilled in the art. Is provided to fully convey the scope of the invention to those skilled in the art, and the invention is only defined by the scope of the claims.

Unless defined otherwise, all terms (including technical or scientific terms) used herein have the same meaning as commonly accepted by the generic art in the prior art to which this invention belongs. Terms defined by generic dictionaries may be interpreted to have the same meaning as in the related art and / or in the text of this application, and may be conceptualized or overly formalized, even if not expressly defined herein I will not.

The terminology used herein is for the purpose of illustrating embodiments and is not intended to be limiting of the present invention. In the present specification, the singular form includes plural forms unless otherwise specified in the specification. As used herein, the terms' comprise 'and / or various forms of use of the verb include, for example,' including, '' including, '' including, '' including, Steps, operations, and / or elements do not preclude the presence or addition of one or more other compositions, components, components, steps, operations, and / or components. The term 'and / or' as used herein refers to each of the listed configurations or various combinations thereof.

It should be noted that the terms such as '~', '~ period', '~ block', 'module', etc. used in the entire specification may mean a unit for processing at least one function or operation. For example, a hardware component, such as a software, FPGA, or ASIC. However, '~ part', '~ period', '~ block', '~ module' are not meant to be limited to software or hardware. Modules may be configured to be addressable storage media and may be configured to play one or more processors. ≪ RTI ID = 0.0 >

Thus, by way of example, the terms 'to', 'to', 'to block', 'to module' may refer to components such as software components, object oriented software components, class components and task components Microcode, circuitry, data, databases, data structures, tables, arrays, and the like, as well as components, Variables. The functions provided in the components and in the sections ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ ' , '~', '~', '~', '~', And '~' modules with additional components.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings attached hereto.

As used herein, the term "structure" is intended to encompass a building, a workpiece, a building, a window, an outdoor advertisement, a bridge, etc. and means all objects placed in space and subjected to wind loads.

When designing the structure, the design wind speed is calculated to calculate the design load by wind. On the other hand, the design wind speed proposed in KBC 2009 can be calculated by the following equation:

As a parameter used to calculate the above equation design velocity, V ₀ is the local base velocity, K _zr is wind speed and high distribution coefficient, K _zt is the importance of the terrain coefficient, I _w is a structure for consideration of the effect of the terrain Coefficient.

Among these, the coefficient of terrain coefficient (K _zt ) is a coefficient considering the terrain type of wind speed addition, and it is set to 1.0 in areas that do not affect the wind like flat land. However, in areas that require wind velocity premium, such as mountains, hills and sloping terrain coefficient including the vertex height (H) height of the surface from the vertex of the terrain by the following equation such, the upwind side of the horizontal distance (L _u) , The horizontal distance (x) between the vertex and the location of the structure, and so forth.

The embodiment of the present invention may collect position and height information from a target area that is initially set in order to calculate a wind load and then set one point in the target area as a target point. Then, an embodiment of the present invention sets a target area around the target point, which is different from the target area, and then obtains the height of the vertex from the target area, passes through the point where the vertex and the structure are located The height of the ground surface from the line can be obtained and the vertex height for calculating the wind load applied to the structure based on the height of the vertex and the ground surface can be calculated.

1 is a block diagram showing a wind load calculation apparatus 100 according to an embodiment of the present invention.

1, the wind load calculation apparatus 100 may include an information collecting unit 111, a target area setting unit 112, and a peak height calculating unit 113.

The information collecting unit 111 may collect position and height information of a plurality of points in the target area. The target area setting unit 112 may set a target point using the position and height information, and may set a target area having a predetermined shape and size around the target point. The vertex height calculating unit 113 calculates the wind load applied to the structure by subtracting the height of the ground surface located on the line passing through the apex of the target area from the vertex of the target area and the point where the structure is located It is possible to calculate the vertex height to be used.

2 is a diagram showing an example of an object area 21 set according to an embodiment of the present invention.

According to an embodiment of the present invention, the information collecting unit 111 may set an area having a predetermined shape and size as the object area including a point where the structure is located.

For example, as shown in FIG. 2, the information collecting unit 111 may set a circular area 21 having a predetermined size around the point 31 where the structure is located as the object area. In this embodiment, the target area 21 is set to a circle, but the shape of the target area is not limited thereto and may be set to any shape, for example, a polygon, an ellipse, a fan shape, or the like.

According to one embodiment, the information collecting unit 111 collects a circular area 21 having a radius of 40 times or less than 3 km of the height of the structure around the point 31 at which the structure is located, Area. However, the size of the target area is not limited thereto, and may be set to various values according to the embodiment.

Then, the information collecting unit 111 may collect position and height information of a plurality of points in the target area 21 set as described above.

According to one embodiment, the information collecting unit 111 acquires information from at least one of a digital map including position and height information of the plurality of points and measurement data obtained by measuring the plurality of points, The position and the height information of the first and second lens groups can be obtained. The measurement data may be data obtained using at least one of a ground survey, a GPS survey, an aerial photogrammetry, a radar survey and a LiDAR survey, but the survey method for obtaining the survey data is not limited thereto .

According to one embodiment, the wind load calculation apparatus 100 may further include a storage unit 12. The storage unit 12 may store position and height information of the plurality of points. In this case, the information collecting unit 111 may acquire the position and height information of the plurality of points by calling the position and height information stored in the storage unit 12. FIG.

According to another embodiment of the present invention, the wind load calculation apparatus 100 may further include a communication unit 10. The communication unit 10 may be connected to a server providing geographical information on the plurality of points.

For example, as shown in FIG. 1, the communication unit 10 may be connected to a server 200, for example, a geographic information system (GIS) that provides geographic information through a wired or wireless network, The controller 111 may obtain position and height information for the plurality of points from the server 200. [

The wind load calculation apparatus 100 may further include an input unit 13, and the position and height information of the plurality of points may be input from the user through the input unit 13, according to an embodiment.

According to one embodiment, the information collecting unit 111 may acquire the position and height information from the elevation point of the electronic map, the node extracted from the contour line, or all of them, but the object area 21 ) ≪ / RTI > points are not limited to elevation points and nodes.

As described above, the information collecting unit 111 can acquire the position and height information of the plurality of points from at least one of the electronic map and the survey data. However, according to the embodiment, the digital elevation model (DEM) .

For example, the information collecting unit 111 firstly acquires the position and height information of a plurality of points in the target area 21, and then, based on the acquired information, (DEM) can be generated. Then, the information collecting unit 111 may acquire position and height information of another plurality of points in the target area 21 from the digital elevation model (DEM).

According to one embodiment, a plurality of points in the target area 21 may be located at equal intervals, but the plurality of points may be arranged at different intervals according to an embodiment. In other words, the plurality of points may be uniformly or unevenly distributed within the object area 21. [

The target area setting unit 112 can newly set the target area using the position and height information collected from the target area 21. [

3 is a diagram showing an example of a target area 22 set for calculating wind load according to an embodiment of the present invention.

According to one embodiment, as shown in FIG. 3, the target area setting unit 112 may set a point 31 at which a structure is located as a target point. Then, a circular area 22 having a predetermined shape and size centered on the target point can be set as a target area.

The target region may be different from the target region. In other words, the target area setting unit 112 may set a target area having a predetermined shape and size around the target point, but different from the target area.

3, the target area 22 is set as a circular area having a height difference between the highest point and the lowest point in the target area 21. However, according to the embodiment, the shape of the target area 22 may be It is not limited to a circle but may be variously set as an ellipse, a polygon, and the like. Also, with respect to the size of the target area 22, the radius of the target area 22 is not limited to a height difference between the highest point and the lowest point in the target area 21, The horizontal distance between the highest point and the lowest point in the region 21, the height of the structure, the input value of the user, and the like.

4 is a view showing an example of a target area 23 set to calculate a wind load according to another embodiment of the present invention.

According to another embodiment, the target area setting unit 112 may set an area having a predetermined shape and size to a first area (e.g., 22 in FIG. 3) around a point 31 at which the structure is located And the highest point (for example, 32 in FIG. 3) in the first area 22 can be set as a target point. Then, the target area setting unit 112 may set a second area (for example, 23 in FIG. 4) having a predetermined shape and size as the target area around the object point 32. [

According to the embodiment, the target region setting unit 112 may repeat the process of setting a new region, and may set the obtained region as a target region.

For example, the target area setting unit 112 sets a first area 22 having a predetermined shape and size around a point 31 where the structure is located, and the first area 22 The region having the predetermined shape and size as the center of the highest point 32 in the second region 23 is set as the second region 23 so that the highest point in the (N-1) th region can be set as the target point . Then, the target region setting unit 112 may set an Nth region having a predetermined shape and size as a target region around the target point. At this time, N is a natural number of 3 or more.

The vertex height calculating unit 113 calculates the vertex height and the height of the ground surface from the target areas 22 and 23 and then subtracts the height of the ground surface from the height of the vertex to calculate a peak height used for calculating the wind load have.

According to one embodiment, the vertex height calculating section 113 may determine the highest point in the target areas 22 and 23 as a vertex.

According to one embodiment, the vertex elevation angle determination section 113 is located at a plurality of points located on lines 302, 303 passing through the highest point in the target area 22, 23 and the point 31 at which the structure is located. The lowest point of the land surface can be determined as the ground surface.

According to another embodiment, the vertex elevation angle determination section 113 is configured to determine the vertex elevation angle of the target area 22, 23 at a plurality of points located on the lines 302, 303 passing through the highest point in the target area 22, The point having the height corresponding to the optimal mode can be determined as the ground surface.

According to yet another embodiment, the vertex elevation angle determination section 113 is configured to determine the vertex elevation height of the target area 22,33 by locating a plurality of vertices 302,303 on the lines 302,303, A point having a height corresponding to the class value of the class having the highest frequency can be determined as the ground surface in the frequency distribution for the height of the point.

According to yet another embodiment, the vertex elevation angle determination section 113 is configured to determine the vertex elevation height of the target area 22,33 by locating a plurality of vertices 302,303 on the lines 302,303, A point having a height corresponding to the rank value of the lowest rank in the frequency distribution of the point height can be determined as the ground surface.

Here, the height used for determining the vertex and the ground surface may be an elevation value of the corresponding point.

According to another embodiment of the present invention, the vertex height calculating section 113 includes an electronic map including position and height information for a plurality of points in the object area 21, (302, 303) passing through the highest point in the target area (22, 23) and a point (31) where the structure is located, using interpolation, based on at least one of the survey data obtained by surveying the point The position and height information of a plurality of points located at the center can be obtained.

The vertex height calculating unit 113 then determines the highest point in the target areas 22 and 23 as a vertex and the lowest point among a plurality of points located on the lines 302 and 303 as an earth surface You can decide.

According to another embodiment, the vertex height calculating unit 113 may determine a point having a height corresponding to an optimal number among a plurality of points located on the lines 302 and 303 as an earth surface.

According to another embodiment, the vertex height calculating unit 113 has a height corresponding to a rank value of the highest degree in a frequency distribution of heights of a plurality of points located on the lines 302 and 303 The point can be determined as the ground surface.

According to another embodiment, the vertex height calculating section 113 calculates a vertex having a height corresponding to the lowest rank value in the frequency distribution of the height of a plurality of points located on the lines 302 and 303 It can be determined by the surface.

According to the embodiment, the vertex height calculating unit 113 may further calculate other parameters for calculating the wind load using the calculated vertex heights.

For example, the vertex height calculating section 113 calculates at least one of the windward side horizontal distance L _u , the windward vertical distance H _d , and the structure vertex horizontal distance x as parameters for calculating the wind load Can be calculated.

Fig. 5 is a side view and a downwind side view of the terrain, which is illustratively shown to explain a parameter calculation process according to an embodiment of the present invention.

According to one embodiment, the vertex height calculating unit 113 may determine the highest point (point 9) in the target areas 22 and 23 as a vertex.

The vertex height calculating unit 113 determines the lowest point (point 2) among the plurality of points on the line passing through the highest point in the target areas 22 and 23 and the point where the structure is located as the surface . According to the embodiment, the vertex height calculating section 113 has a height corresponding to an optimal number among a plurality of points located on a line passing through a highest point in the target areas 22 and 23 and a point at which the structure is located; A point having a height corresponding to a rank value of the highest degree in a frequency distribution for the height of the plurality of points; Or a point having a height corresponding to the lowest rank value in the frequency distribution for the height of the plurality of points may be determined as the ground surface.

According to one embodiment, the vertex height calculating unit 113 may calculate the vertex height H by calculating a difference between the height of the vertex (point 9) and the height of the ground surface (point 2). For example, when the height h ₉ of the vertex (point 9) is 40 m and the height h ₂ of the ground surface (point 2) is 10 m, the parameter calculator 113 calculates h ₉ - h ₂ = 30 m can be estimated as the vertex height (H).

According to an embodiment of the present invention, the vertex height calculating unit 113 may calculate a difference between a height of the vertex and a height of each of the points located on the windward side slope. For example, 5, the vertex height calculation unit 113 has a vertex (point 9), and the upwind side of the inclined surface the points located on the (point 1 to point 8), the height between the respective car (h ₉ - h _{1 , h 9 - h 2, h} 9 - h 3, h 9 - h 4, h 9 - h 5, h 9 - h 6, h 9 - h 7, h 9 - can be calculated h _8).

Then, the vertex height calculating unit 113 can determine a point nearest to a half of the difference between the height of the vertex and the height of the ground surface (i.e., the vertex height H). Referring to FIG. 5, the point at which the height difference from the vertex (point 9) closest to half (H / 2) of the vertex height corresponds to point 6.

The vertex height calculating unit 113 may calculate the horizontal distance L _u by calculating the horizontal distance between the determined point and the vertex. For example, referring to FIG. 5, the parameter calculator 113 may calculate a horizontal distance L _u by calculating a horizontal distance between a point 6 and a vertex 9.

According to an exemplary embodiment, when the points are spaced apart by the same distance, it is possible to calculate the windward side horizontal distance L _u by calculating a multiple of the interval. For example, when the interval between points is set to 10 m in FIG. 2, the vertex height calculating unit 113 can calculate 10 占 (9 - 6) = 30 m as the upward horizontal distance L _u have.

According to another embodiment of the present invention, the vertex height calculating unit 113 can determine a point at which the height difference corresponds to H / 2 using interpolation.

According to this embodiment, the vertex height calculating section 113 can calculate the height difference between the vertex height and each of the points located on the windward side slope. Then, the vertex height calculating section 113 can determine the first point closest to the half (H / 2) of the difference between the height of the vertex and the height of the earth surface and the second point closest to the second point. For example, referring to FIG. 5, the first point closest to the H / 2 height difference is point 6, and the second closest point corresponds to point 7.

Then, using the interpolation from the first point and the second point, the parameter calculator 113 calculates the height difference from the vertex to a half (H / 2) of the difference between the height of the vertex and the height of the earth surface Can be calculated.

6 is a view for explaining a process of calculating the horizontal distance on the windward side of the terrain by using interpolation according to an embodiment of the present invention.

6, the vertex height calculating section 113 calculates the height difference from the vertex (point 9) using interpolation from the first point (point 6) and the second point (point 7) to H / 2 The corresponding point 65 can be calculated. For example, if the height of the first point (point 6) is 22 m, the height of the second point (point 7) is 29 m, the height of the vertex (point 9) is 40 m, and a height of 10 m, a first point (point 6) and when the second point horizontal distance between (point 7) of 10 m, a vertex (point 9), and the height difference between _{h / 2 = (h 9 -} h 2) The height of the point 65 corresponding to / 2 = 15 m is 25 m. In one embodiment, when linear interpolation is performed using a linear function, the horizontal distance between point 65 and point 7 is 10 X (h ₇ - h ₆₅ ) / (h ₇ - h ₆ ) 25) / (29 - 22)? 5.7 m.

The vertex height calculating unit 113 may calculate the horizontal distance L _u by calculating the horizontal distance between the point 65 and the vertex (point 9). For example, since the horizontal distance between the point 65 and the point 7 is 5.7 m and the horizontal distance between the points 7 and 9 is 10 X (9 - 7) = 20 m, 25.7 m can be calculated as the horizontal distance L _u on the windward side of the terrain.

As described above, the vertex height calculating unit 113 can calculate the horizontal distance L _{u of} the terrain by using at least one of the position information and the height information of a plurality of points.

According to one embodiment of the invention, the vertex height calculation unit 113 may calculate the vertical distance downwind branched water (H _d) using at least one of the location information and the height information.

According to one embodiment, the vertex height calculating unit 113 may calculate a straight line distance between vertexes and each of the points located on the downwind side slope. 5, the vertex height calculating section 113 can calculate a straight line distance L between a vertex (point 9) and each of points (points 10 to 21) located on the downward sloping surface .

Then, the vertex height calculating unit 113 can determine a point at which the straight line distance is closest to five times (5H) of the difference between the height of the vertex and the height of the ground surface. Referring to FIG. 5, the point nearest to the vertex 5H (5H) of the vertex height corresponds to the point 21.

Then, the vertex height calculating unit 113 may calculate the windward vertical distance H _d by calculating a difference between the height of the determined point and the height of the vertex. Referring to FIG. 5, the vertex height calculating unit 113 may calculate a height difference between the point 21 and the vertex (point 9) to calculate the downwind vertical distance H _d . For example, when the height of the point 21 is 11 m, the vertex height calculating section 113 can calculate h ₉ - h ₂₁ = 40 - 11 = 29 m as the downward vertical distance (H _d ).

According to another embodiment of the present invention, the vertex height calculation unit 113 may determine a point corresponding to a linear distance of 5H using interpolation.

According to this embodiment, the vertex height calculating section 113 can calculate the straight line distance L between points located on the vertex and the downward sloping surface. Then, the straight line distance can determine the first point closest to the fifth point (5H) of the difference between the height of the vertex and the height of the earth surface and the second point closest to the second point. For example, referring to FIG. 5, the first point closest to the straight line distance 5H is point 21, and the second closest point corresponds to point 20.

Then, using the interpolation from the first point and the second point, the vertex height calculating section 113 calculates the straight line distance L from the vertex to five times (5H) the difference between the height of the vertex and the height of the earth surface, Can be calculated.

7 is a view for explaining a process of calculating a vertical distance of a downwind side of a terrain by using interpolation according to an embodiment of the present invention.

7, the vertex height calculating section 113 calculates a straight line distance from the vertex (point 9) using interpolation from the first point (point 21) and the second point (point 20) to 5H A point 205 at which a point of intersection can be calculated. For example, if the height of the first point (point 21) is 11 m, the height of the second point (point 20) is 13 m, the height of the vertex (point 9) is 40 m, The horizontal distance between the first point (point 21) and the second point (point 20) is 10 m and the linear distance L ₂₁ between the vertex (point 9) and the first point (point 21) is 152 m , And the straight line distance L ₂₀ between the vertex (point 9) and the second point (point 20) is 146 m, the vertex height calculating section 113 calculates the height difference h between the point 20 and the point 205 as follows You can get:

_{h = (L 205 - L 20} ) / (L 21 - L 20) × (h 20 - h 21) = (150 - 146) / (152 - 146) × (13 - 11) ≒ 1.3 m

The vertex height calculating unit 113 may then calculate the vertical distance between the point 205 and the vertex (point 9) to calculate the downwind vertical distance H _d . For example, as described above, since the vertical distance between the point 20 and the point 205 is 1.3 m and the vertical distance between the point 9 and the point 20 is h ₉ - h ₂₀ = 40 - 13 = 27 m, (H _d ) of the topography of the above-mentioned terrain.

According to an embodiment of the present invention, the vertex height calculating unit 113 may calculate the horizontal distance x of the structure peak by calculating the horizontal distance between the vertex and the point nearest to the location of the structure. 5, when the point closest to the point where the structure is located is the point 18, the vertex height calculating unit 113 calculates 10 x (18 - 9) = 90 m as the structure vertex horizontal distance x Can be calculated. According to an embodiment, when the structure is located between two points, the vertex height calculating section 113 may calculate the structure vertex horizontal distance (x) using the interpolation from the two points.

Referring again to FIG. 1, the wind load calculation apparatus 100 may further include a terrain coefficient calculation unit 114.

The terrain coefficient calculating unit 114 may calculate the terrain coefficient based on the estimated parameters. The terrain coefficient calculation unit 114 may calculate the terrain coefficient by substituting the calculated H, L _u , H _d , x and the height z from the surface of the ground to calculate the design wind speed into Equation (2).

The information collecting unit 111, the target area setting unit 112, the elevation height calculating unit 113, and the terrain coefficient calculating unit 114 execute a program for calculating a wind load to calculate a wind load, for example, And a CPU. In addition, the program may be stored in the storage unit 12, and the wind load calculation apparatus 100 may execute the program from the storage unit 12 and execute the program.

The wind load calculation apparatus 100 according to an embodiment of the present invention may further include an output unit 14. The output unit 14 may output the parameter or the wind load calculated according to an embodiment of the present invention and provide it to the user. According to one embodiment, the output unit 14 may include a display for visually displaying predetermined information, for example, an LCD, a PDP.

8 is a flowchart illustrating a wind load calculation method 300 according to an embodiment of the present invention.

The wind load calculation method 300 may be performed by the wind load calculation apparatus 100 according to the embodiment of the present invention described above.

8, the wind load calculation method 300 may include collecting position and height information of a plurality of points in the target area 21 (S310), setting a target point using the position and height information (S320) of setting a region having a predetermined shape and size around the target point as a target region (22, 23), and a step (S320) (S330) by subtracting the height of the surface of the ground located on the lines 302 and 303 passing through the vertex of the vertexes 22 and 23 and the point 31 where the structure is located .

According to one embodiment, the step of collecting the position and height information S310 includes the step of setting an area including the point 31 where the structure is located and having a predetermined shape and size as the object area 21 .

According to one embodiment, the step of collecting the position and height information (S310) includes a step of acquiring position and height information from at least one of an electronic map including geographical information on a plurality of points and measurement data obtained by measuring a plurality of points, And acquiring the information.

According to another embodiment, the step S310 of collecting the position and height information may include generating a digital elevation model for the object area 21 using at least one of the electronic map and the survey data, And obtaining position and height information from the numerical elevation model.

According to an exemplary embodiment of the present invention, the step of setting the target area (S320) may include setting a point (31) where the structure is located as the target point and setting a predetermined shape and size And setting the region 22 having the target region as the target region. The target region may be different from the target region. In other words, the step of setting the target area (S320) may include setting a target area having a predetermined shape and size around the target point but different from the target area.

According to another embodiment of the present invention, the step of setting the target area (S320) may include setting a region having a predetermined shape and size centered on a point (31) where the structure is located as a first area (22) , Setting a highest point (32) in the first area (22) as the target point, and setting a second area (23) having a predetermined shape and size around the target point as the target area Step < / RTI >

According to an embodiment of the present invention, the step of setting the target area (S320) may include setting a region having a predetermined shape and size around a point (31) where the structure is located as a first region (22) 1 region 22 is set as the second region 23 by repeating the process of setting the region having the predetermined shape and size as the center around the highest point 32 in the region 22, And setting an Nth area having a predetermined shape and size as a target area around the object point. At this time, N is a natural number of 3 or more.

Here, the shape of the area is not limited to a circle, and may be variously set as an ellipse, a polygon, or the like. Further, with respect to the size of the region, the radius of the target region 22, 23 is not only the height difference between the highest point and the lowest point in the object region 21, The horizontal distance between the lowest point, the height of the structure, the input value of the user, and the like.

According to an exemplary embodiment, the step of calculating the peak height (S330) may include determining the highest point in the target areas 22 and 23 as a vertex.

The step of calculating the vertex height S330 may include calculating a vertex height among a plurality of points located on the line images 302 and 303 passing through the highest point in the target areas 22 and 23 and the point 31 where the structure is located And determining the lowest point as the ground surface. According to an embodiment, the point determined as the ground surface may be a point having a height corresponding to the optimal number among a plurality of points located in the line images 302 and 303, A point having a height corresponding to the class value of the class or a point having a height corresponding to the class value of the lowest class in the frequency distribution for the height of the plurality of points.

According to another embodiment, the step of calculating the vertex height S330 may include an electronic map including position and height information of a plurality of points in the target area 21, On the lines 302 and 303 passing through the highest point in the target area 22 and 23 and the point 31 where the structure is located, using interpolation, based on at least one of the survey data obtained by surveying the point Obtaining position and height information of a plurality of points located; And determining the highest point in the target area (22, 23) as a vertex.

The step of calculating the vertex height S330 may include calculating a vertex height among a plurality of points located on the line images 302 and 303 passing through the highest point in the target areas 22 and 23 and the point 31 where the structure is located And determining the lowest point as the ground surface. According to an embodiment, the point determined as the ground surface may be a point having a height corresponding to the optimal number among a plurality of points located on the line images 302 and 303, A point having a height corresponding to the class value of the class or a point having a height corresponding to the class value of the lowest class in the frequency distribution for the height of the plurality of points.

The plurality of points may be uniformly distributed on the lines 301 and 302, but may be nonuniformly distributed depending on the embodiment.

According to an embodiment of the present invention, the wind load calculation method 300 may further include calculating other parameters for calculating the wind load using the estimated peak height (H).

For example, the more-calculated parameter may include at least one of a windward side horizontal distance L _u , a windward side vertical distance H _d , and a structure vertex horizontal distance x.

According to one embodiment, the step of estimating the parameter may include calculating a difference between a height of the vertex and a height of each of the points located on the windward side slope, a difference in height between the height of the vertex and the ground surface, Calculating a horizontal distance between the determined point and the vertex and calculating a windward horizontal distance L _u by calculating a horizontal distance between the determined point and the vertex.

According to another embodiment, the step of estimating the parameter may also calculate the windward side horizontal distance L _u using an interpolation method. For example, the step of estimating the parameter may include calculating a difference between a height of the vertex and a height of each of the points located on the windward side slope, calculating a difference between the height of the vertex and the height of the ground surface, 2) from the first point and the second point, calculating a point at which the height difference from the apex is H / 2 using the interpolation from the first point and the second point And calculating a horizontal distance between the estimated point and the vertex to calculate the windward side horizontal distance L _u .

According to one embodiment, the step of estimating the parameter may estimate the downwind vertical distance (H _d ) from the position and height information for a plurality of points. For example, the step of estimating the parameters may include calculating a straight line distance between the vertex and each of the points located on the downhill slope, calculating the straight line distance to five times (5H) the difference between the height of the vertex and the height of the surface Determining a nearest point, and calculating a height difference between the determined point and the vertex to calculate a downhill vertical distance (H _d ).

According to another embodiment, the step of estimating the parameter may calculate the downward vertical distance (H _d ) by interpolation. For example, the step of calculating the parameter may include calculating a straight line distance between the vertex and each of the points located on the downward sloping surface, and calculating the straight line distance to be 5 times the height difference between the vertex height and the ground surface Calculating a point at which the linear distance from the first point and the second point to the vertex corresponds to 5H using the interpolation from the first point and the second point; And calculating a vertical distance between the estimated point and the vertex to calculate the vertical distance on the downwind side.

According to one embodiment, estimating the parameter may include calculating a horizontal distance between the vertex and a point closest to the structure to estimate the structure vertex horizontal distance (x).

According to an embodiment of the present invention, the wind load calculation method 300 may further include calculating a terrain factor based on the calculated parameters.

The wind load calculation method 300 according to an embodiment of the present invention may be stored in a computer-readable recording medium that is manufactured as a program to be executed in a computer. The computer-readable recording medium includes all kinds of storage devices in which data that can be read by a computer system is stored. Examples of the computer-readable recording medium include ROM, RAM, CD-ROM, magnetic tape, floppy disk, optical data storage, and the like.

According to the wind load calculation device and method described above, the surrounding terrain as the wind load calculation standard can be determined objectively and quantitatively without being determined by the subjective judgment of the designer. As a result, the wind loads that are reasonably reflected on the wind by the surrounding topography of the structure can be calculated, and the safety and economical efficiency of the structure can be improved.

100: Wind load calculation device
10:
111: Information collecting section
112: target area setting unit
113: Vertex height calculation
114: terrain coefficient calculation unit
12:
13:
14: Output section

Claims (15)

An information collecting unit for collecting position and height information of a plurality of points in a target area;
A target area setting unit setting a target point using the position and height information, and setting an area having a predetermined shape and size as a target area around the target point; And
A vertex height for calculating a vertex height for calculating a wind load applied to the structure by subtracting a height of a ground surface located on a line passing from a vertex of the target area to a point where the structure is located, And a calculation section,
Wherein the target area setting unit comprises:
And a region having a size corresponding to a height difference or a horizontal distance between a predetermined shape centered on the object point and a highest point and a lowest point in the object region, Target area, or
Setting a region having a predetermined shape and size around a point where the structure is located as a first region and setting a region having a predetermined shape and size as a center around a highest point in the first region as a second region To set the highest point in the (N-1) th region as the target point, and sets the Nth region having the predetermined shape and size as the target region around the target point. The method according to claim 1,
Wherein the information collecting unit comprises:
An electronic map including position and height information for the plurality of points; And
Surveying data obtained by surveying the plurality of points;
To obtain the position and height information from at least one of the position and the height information. The method according to claim 1,
Wherein the information collecting unit comprises:
An electronic map including geographic information on the target area; And
Survey data obtained by surveying the target area;
(DEM) for the target area, and acquires the position and height information from the digital elevation model. delete The method according to claim 1,
The vertex height calculation unit may include:
Determining the highest point in the target area as the vertex,
A lowest point among a plurality of points located on a line passing through a highest point in the target area and a point where the structure is located;
A point having a height corresponding to an optimal one of a plurality of points located on a line passing through a highest point in the target area and a point where the structure is located;
A point having a height corresponding to a rank of the highest degree in a frequency distribution of heights of a plurality of points located on a line passing through a highest point in the target area and a point where the structure is located; or
Determining a point having a height corresponding to a lowest rank value in a frequency distribution of a height of a plurality of points located on a line passing through the highest point in the target area and a point at which the structure is located, Output device. The method according to claim 1,
The vertex height calculation unit may include:
Using an interpolation method based on at least one of an electronic map including position and height information for a plurality of points in the object area and measurement data obtained by measuring a plurality of points in the object area, Acquiring position and height information of a plurality of points located on a line passing through a point and a point at which the structure is located,
Determining the highest point in the target area as the vertex,
A lowest point among a plurality of points located on a line passing through a highest point in the target area and a point where the structure is located;
A point having a height corresponding to an optimal one of a plurality of points located on a line passing through a highest point in the target area and a point where the structure is located;
A point having a height corresponding to a rank of the highest degree in a frequency distribution of heights of a plurality of points located on a line passing through a highest point in the target area and a point where the structure is located; or
Determining a point having a height corresponding to a lowest rank value in a frequency distribution of a height of a plurality of points located on a line passing through the highest point in the target area and a point at which the structure is located, Output device. The method according to claim 1,
And a terrain coefficient calculating unit for calculating a terrain coefficient based on the vertex height. Collecting position and height information of a plurality of points in the object area;
Setting a target point using the position and height information, and setting an area having a predetermined shape and size as a target area around the target point; And
Calculating a peak height for calculating a wind load applied to the structure by subtracting a height of a ground surface located on a line passing a peak of the target region from a peak of the target region and a point where the structure is located, ≪ / RTI &
Wherein setting the target region comprises:
And a region having a size corresponding to a height difference or a horizontal distance between a predetermined shape centered on the object point and a highest point and a lowest point in the object region, Target area, or
Setting a region having a predetermined shape and size around a point where the structure is located as a first region and setting a region having a predetermined shape and size as a center around a highest point in the first region as a second region Setting the highest point in the (N-1) th area as the object point, and setting an Nth area having the predetermined shape and size as the target area around the object point, Wind load calculation method. 9. The method of claim 8,
The step of collecting the position and height information comprises:
An electronic map including position and height information for the plurality of points; And
Surveying data obtained by surveying the plurality of points;
And obtaining the position and height information from at least one of the position and the height information. 9. The method of claim 8,
The step of collecting the position and height information comprises:
Generating a digital elevation model for the target area using at least one of an electronic map including geographic information on the target area and survey data obtained by surveying the target area; And
Obtaining the position and height information from the digital elevation model;
To calculate a wind load. delete 9. The method of claim 8,
The step of estimating the vertex height comprises:
Determining the highest point in the target area as the vertex; And
The lowest point of the plurality of points located on the line passing through the highest point in the target area and the point where the structure is located,
A point having a height corresponding to an optimal one of a plurality of points located on a line passing through a highest point in the target area and a point where the structure is located,
A point having a height corresponding to a rank of the highest degree in a frequency distribution of heights of a plurality of points located on a line passing through the highest point in the target area and a point at which the structure is located,
Determining a point having a height corresponding to a lowest rank in a frequency distribution of a height of a plurality of points located on a line passing through a highest point in the target area and a point at which the structure is located as the ground surface ;
To calculate a wind load. 9. The method of claim 8,
The step of estimating the vertex height comprises:
Using an interpolation method based on at least one of an electronic map including position and height information for a plurality of points in the object area and measurement data obtained by measuring a plurality of points in the object area, Obtaining position and height information of a plurality of points located on a line passing through a point and a point where the structure is located;
Determining the highest point in the target area as the vertex; And
The lowest point of the plurality of points located on the line passing through the highest point in the target area and the point where the structure is located,
A point having a height corresponding to an optimal one of a plurality of points located on a line passing through a highest point in the target area and a point where the structure is located,
A point having a height corresponding to a rank of the highest degree in a frequency distribution of heights of a plurality of points located on a line passing through the highest point in the target area and a point at which the structure is located,
Determining a point having a height corresponding to a lowest rank in a frequency distribution of a height of a plurality of points located on a line passing through a highest point in the target area and a point at which the structure is located as the ground surface ;
To calculate a wind load. 9. The method of claim 8,
And calculating a terrain coefficient based on the peak height. A computer-readable recording medium,
A recording medium on which a program for executing a wind load calculation method according to any one of claims 8 to 10, and 12 to 14 is stored.

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