KR20140105278A - Apparatus and method for calculating design wind speed by collecting samples - Google Patents

Abstract

The present invention relates to a device for calculating design wind by collecting a sample and a method thereof. The device for calculating the design wind according to one embodiment of the present invention comprises a sample point information collecting unit which collects the position information and the altitude information of a plurality of sample points in an object area; a target point information obtaining unit which generates a plurality of target points in the object area and obtains the altitude information of a target point based on the position information and the altitude information of a sample point; a ground surface height calculating unit which calculates the height of a ground surface of the object area based on the altitude information of the target point; a frequency distribution calculating unit which calculates the difference value between total height in which the height of a building is applied to an altitude for each target point and the height of the ground surface and calculates frequency distribution for the difference value; a parameter calculating unit which assigns ground surface illumination to a level of the frequency distribution, applies a weight value based on the frequency distribution to a parameter which is set per the ground surface illumination; and a design wind calculating unit which calculates the design wind of the object area by using the calculated parameter.

Description

[0001] APPARATUS AND METHOD FOR CALCULATING DESIGN WIND SPEED BY COLLECTING SAMPLES [0002]

The present invention relates to an apparatus and method for estimating a design wind speed through sample collection.

The influence of wind in the design of buildings is one of the items to be considered. Wind characteristics such as wind speed or wind direction can be affected by the surrounding area, and if the wind velocity is accelerated by the surrounding area, the safety of the building can be threatened. In order to take into account the load the wind makes on the building, it is necessary to calculate the wind load in designing the building and the design wind speed in order to calculate the wind load.

In the process of estimating the design wind speed, the parameter values used in the calculation of the design wind speed are determined according to the surface roughness representing the surface roughness. Conventionally, such ground surface roughness has been determined by subjective judgment of the designer, and the parameter values are not objectively and reasonably estimated.

An object of the present invention is to provide an apparatus and method for designing a wind speed which can more objectively and reasonably calculate a parameter value used for calculation of a design wind speed and calculate a more appropriate design wind speed.

The apparatus for estimating wind velocity according to an embodiment of the present invention includes a sample point information collecting unit for collecting position information and altitude information of a plurality of sample points in a target area; A target point information obtaining unit that creates a plurality of target points within the target area and obtains elevation information of the target point based on position information and elevation information of the sample points; A ground surface height calculating unit for calculating a ground surface height of the target area based on the elevation information of the target point; A frequency distribution calculating unit for calculating a difference value between the total height of the elevation reflecting the building height and the height of the ground surface for each target point and calculating a frequency distribution of the difference; A parameter value calculating unit for assigning a surface roughness to the rank of the frequency distribution and calculating a parameter value of the target area by applying a weight based on the frequency distribution to the parameter value set for each of the surface roughnesses; And a design wind speed calculation unit for calculating the design wind speed of the target area using the calculated parameter value.

The sample point information collecting unit may include: an electronic map of the object area; And survey data obtained by surveying the target area; The position information and the altitude information of the sample point can be collected from at least one of the sample points.

The target point information obtaining unit may generate the target point on a building located in the target area.

The target point information obtaining unit may generate the target points at equal intervals in the target area.

Wherein the target point information obtaining unit is configured to generate a digital elevation model (DEM) of the target area by using the position information and the elevation information of the sample point, and calculate an elevation value corresponding to a position of the target point in the digital elevation model (DEM) Can be calculated as the elevation information of the target point.

The target point information obtaining unit may calculate elevation information of the target point using an interpolation method based on the position information and the elevation information of the sample point.

The ground surface height calculating section may calculate the height of the target point by: a minimum value of the elevation of the target point; An optimal elevation of the elevation of the target point; A rank value of the highest rank in the frequency distribution of the elevation of the target point; An average value of altitudes belonging to a class having the highest frequency in the frequency distribution of the elevation of the target point; A rank value of the lowest rank in the frequency distribution of the elevation of the target point; Or an average value of altitudes belonging to the lowest rank in the frequency distribution of the elevation of the target point;

The total height can be calculated by summing the height of the building on the elevation.

The height of the building can be calculated by multiplying the number of the ground floor of the building by a predetermined height.

The parameter value calculation unit may assign the surface roughness according to a rank value of the rank.

The parameter value may include at least one of the wind speed altitude distribution coefficient, the terrain coefficient, the turbulence intensity, the wind speed altitude distribution index, the reference rough wind height, and the atmospheric boundary layer start height.

The parameter value calculation unit may calculate the relative degrees of each rank and add the calculated values by multiplying the parameter values set for each of the ground surface roughnesses by the relative degrees.

The method for estimating the design wind speed according to an embodiment of the present invention includes the steps of acquiring elevation information of a target point using position information and elevation information of a sample point collected from a target area, Calculating a parameter value of the target area by applying a weight to a parameter value set for each of the ground surface roughnesses based on the frequency distribution, and calculating a parameter value of the target area by using the calculated parameter value, The design wind speed can be calculated.

According to an embodiment of the present invention, there is provided a method for calculating wind speed, comprising: collecting position information and altitude information of a plurality of sample points in a target area; Generating a plurality of target points within the target area and obtaining elevation information of the target point based on the position information and elevation information of the sample point; Calculating a height of a surface of the target area based on elevation information of the target point; Calculating a difference value between the height of the ground surface and the total height of the elevation reflecting the height of the building for each target point and calculating a frequency distribution of the difference; Calculating a parameter value of the target area by assigning a surface roughness to the rank of the frequency distribution and applying a weight based on the frequency distribution to a parameter value set for each of the surface roughnesses; And calculating the design wind speed of the target area using the calculated parameter value.

The step of obtaining the elevation information of the target point may comprise: generating the target point on a building located within the target area.

The step of obtaining elevation information of the target point may include: generating the target point at equal intervals in the target area.

The step of obtaining the elevation information of the target point may include: generating a digital elevation model (DEM) of the object area using the position information and the elevation information of the sample point; And calculating an elevation corresponding to the position of the target point in the digital elevation model (DEM) as elevation information of the corresponding target point.

The step of obtaining the elevation information of the target point may include: calculating elevation information of the target point using an interpolation method based on the position information and the elevation information of the sample point.

The total height can be calculated by summing the height of the building on the elevation.

The height of the building can be calculated by multiplying the number of the ground floor of the building by a predetermined height.

The design wind speed calculation method according to an 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, it is possible to prevent the parameter value used for calculating the design wind speed from being improperly determined by the ground surface roughness judged by the designer.

According to an embodiment of the present invention, it is possible to prevent the design wind speed from being calculated to be excessively high or low, thereby improving the economics and safety of the building.

1 is a block diagram showing a design wind speed estimating apparatus according to an embodiment of the present invention.
2 is a diagram illustrating an example of an object area where a design wind speed is estimated according to an embodiment of the present invention.
Figure 3 is an illustration of an example of a target point created within an object area in accordance with an embodiment of the present invention.
4 is a diagram illustrating an example of a target point created within an object region in accordance with another embodiment of the present invention.
5 and 6 are views showing an example of a target point generated in a target area according to another embodiment of the present invention.
7 is an exemplary graph illustrating the elevation of the elevation of a plurality of target points in an area of interest in accordance with an embodiment of the present invention.
8 is an exemplary frequency distribution diagram illustrating frequency distributions for altitudes of a plurality of target points in an object area in accordance with an embodiment of the present invention.
9 is an exemplary diagram illustrating a process of determining the total height of a target point according to an embodiment of the present invention.
10 is an example of a frequency distribution diagram showing a frequency distribution calculated with respect to a difference value between a total height of a plurality of target points in a target area and a height of a ground surface according to an embodiment of the present invention.
11 is a table exemplarily showing parameter values set for each surface roughness according to an embodiment of the present invention.
12 is a view for explaining a design wind speed calculation method according to an embodiment of the present invention.

Other advantages and features of the present invention and methods of achieving them will become apparent with reference to the embodiments described below in detail with reference to 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' 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.

In building design, 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:

In the above equation, V ₀ is the basic wind speed in the region, K _zr is the wind speed altitude distribution coefficient, K _zt is the terrain factor to take into account the influence of the terrain, I _w is the importance coefficient of the building to be.

The wind velocity altitude distribution coefficient (K _zr ) is given in Table 1 below considering the surface roughness of the building site and the corresponding height of the atmospheric boundary layer starting point (Z _b ), the height of the reference draft wind (Z _g ) and the wind speed altitude distribution index Lt; / RTI >

In addition, the atmospheric boundary layer starting height (Z _b ), the reference hard wind height (Z _g ) and the wind speed altitude distribution index (α) are determined as shown in Table 2 according to the surface roughness.

The surface roughness proposed in KBC 2009 is classified as shown in Table 3 according to the surface condition of the area around the construction site.

The geomorphic coefficient (K _zt ) is a factor that takes account of the wind speed addition by the topography, and is set to 1.0 in areas that do not affect the wind like flat land. However, in areas where a wind velocity premium is required, such as mountains, hills, and slopes, the terrain factor can be calculated by the following equation:

The basic wind speed (V ₀ ) is the local wind velocity applied to the design wind speed as a default, and is the wind velocity corresponding to the 100-year repetition period of the average wind speed for 10 minutes at the ground surface height of 10 m at the ground surface roughness C. The basic wind speed is calculated as follows according to the location where the construction site is located. However, if the construction site is located between the wind speed lines, the values between the wind speed lines can be interpolated.

The importance coefficient (I _w ) is a coefficient representing the safety factor according to the years of use of the building, and is calculated as follows considering the importance of the building:

One embodiment of the present invention can collect data of a sample point from an object area in the design wind speed estimation and obtain elevation information of the target point based on the collected data. Then, the frequency distribution is calculated from the data based on the elevation information of the target point and the building information, and the parameter value used for the design wind speed estimation can be calculated using the frequency distribution.

1 is a block diagram showing a design wind speed estimating apparatus according to an embodiment of the present invention.

1, the design wind speed estimating apparatus 100 includes a sample point information collecting unit 111, a target point information obtaining unit 112, a surface height calculating unit 113, a frequency distribution calculating unit 114, A parameter value calculation unit 115, and a design wind speed calculation unit 116. [

The sample point information collecting unit 111 may collect position information and elevation information of a plurality of sample points in the object area. The target point information obtaining unit 112 may generate a plurality of target points within the target area and obtain elevation information of the target point based on the position information and the elevation information of the sample point. The ground surface height calculation unit 113 may calculate the ground surface height of the target area based on the elevation information of the target point. The frequency distribution calculating unit 114 may calculate a difference value between the total height of the building height at the elevation and the height of the earth surface for each target point and calculate the frequency distribution of the difference value. The parameter value calculation unit 115 calculates the parameter value of the target area by assigning the surface roughness to the rank of the frequency distribution and applying a weight based on the frequency distribution to the parameter value set for each of the surface roughnesses . The design wind speed calculation unit 116 can calculate the design wind speed of the target area using the calculated parameter value.

According to an embodiment of the present invention, the design wind speed estimating apparatus 100 may further include a storage unit 12. The storage unit 12 may store geographical information on the target area.

For example, the storage unit 12 may store at least one of a digital map of the target area and measurement data obtained by measuring the target area. 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 sample point information collecting unit 111 may collect geographical information and elevation information of a plurality of sample points in the object area by calling up the geographical information stored in the storage unit 12.

According to another embodiment of the present invention, the design wind speed 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 target area.

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), which provides geographic information through a wired or wireless network, The collection unit 111 may receive the geographical information about the target area from the server 200 and collect the location information and the altitude information of the sample point.

The geographical information on the target area provided by the server 200 may include at least one of a digital map of the target area and survey data obtained by measuring the target area. 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 an embodiment, the design wind speed estimating apparatus 100 may further include an input unit 13, and the location information and elevation information of the sample point may be input from a user through the input unit 13. [

2 is a diagram illustrating an example of an object area where a design wind speed is estimated according to an embodiment of the present invention.

As shown in FIG. 2, the object area 20 may be a circular area. According to one embodiment, the object area 20 may be a circular area having a predetermined radius centered on the predetermined point 21.

For example, the target area 20 may be a circular area having a small radius of 40 times or 3 km of the height of the building at the construction site, but the shape or size of the area is not limited thereto And can have any shape or size. For example, the target area may be a polygonal area or a fan-shaped area.

According to an embodiment of the present invention, the input unit 13 may receive data for setting the target area 20 from a user.

For example, in order to set the target area 20 shown in Fig. 2, the user inputs data specifying the construction point of the building, for example, latitude and longitude data of the construction point through the input unit 13, Can be input. Then, the design wind speed estimating apparatus 100 can set a circular area having a small radius of 40 times or 3 km of the building height at the center 21 as the input construction point, The size is not limited thereto. According to the embodiment, the shape and size of the target area may be inputted from the user through the input unit 13.

In addition, the data designating the construction point of the building is not limited to the latitude and longitude data of the construction point, and may include the building number of the construction point, GPS data, and the like according to the embodiment.

According to an embodiment of the present invention, the sample point information collection unit 111 may extract a high point from an electronic map of the object area 20 and designate the extracted high point as a sample point. According to another embodiment, the sample point information collecting unit 111 may extract a reference point from an electronic map of the object area 20 and designate the reference point as a sample point. According to the embodiment, the sample point information collecting unit 111 may extract both the elevation point and the reference point and designate the sample point as the sample point, but the position of the sample point is not limited thereto.

According to one embodiment, the location information of the sample point may include absolute coordinates composed of latitude and longitude data of a corresponding point, but may include relative coordinates based on an arbitrary point according to an embodiment.

The target point information obtaining unit 112 may generate a plurality of target points in the target area 20. [

Figure 3 is an illustration of an example of a target point created within a subject area 20 in accordance with one embodiment of the present invention.

3, the target point information obtaining unit 112 may generate a target point X on a building located in the target area 20, according to an embodiment of the present invention. In other words, the position of the target point X can be specified at the point where the building is located in the object area 20.

According to one embodiment, the location of the target point X may be created at the center of the building, but the location of the target point is not limited thereto and may be created at any point on the building according to an embodiment.

In the embodiment shown in FIG. 3, the target point X is designated only for the building, but according to the embodiment, some of the target points may also be assigned to the ground or the water surface in the object area 20. According to the embodiment, the position of the target point X may be input from the user through the input unit 13 and designated.

4 is a diagram illustrating an example of a target point created within an object region in accordance with another embodiment of the present invention.

The target point information obtaining unit 112 may generate the digital elevation model (DEM) of the object area 20 using the position information and the elevation information of the sample point.

In this embodiment, the target point information obtaining unit 112 may generate the target point X corresponding to the grid of the digital elevation model (DEM). For example, as shown in FIG. 4, the target point X may be assigned to a node formed by a grid of a digital elevation model (DEM).

5 is a view showing an example of a target point created in a target area according to another embodiment of the present invention.

As shown in FIG. 5, according to another embodiment of the present invention, the target point information obtaining unit 112 may generate the target points X at the same intervals in the target area 20. In other words, the target point X can be specified to be evenly distributed within the object area 20. [

Although the embodiment shown in Fig. 5 is designed to uniformly distribute the target points X at equal intervals, according to the embodiment, as shown in Fig. 6, the target points X are arranged at different intervals from each other, It may also be distributed.

According to an embodiment of the present invention, the target point information obtaining unit 112 obtains an elevation corresponding to the position of the target point X in the digital elevation model (DEM) of the target area 20, It can be calculated by elevation information.

According to another embodiment of the present invention, the target point information obtaining unit 112 may calculate elevation information of the target point X using an interpolation method based on the position information and the elevation information of the sample point . The target point information obtaining unit 112 may use linear interpolation, nonlinear interpolation or Natural Neighbor interpolation to calculate elevation information of the target point X, but the interpolation method used is not limited thereto.

The ground surface height calculation unit 113 may calculate the ground surface height of the object area 20 based on the elevation information of the target point X. [

According to an embodiment of the present invention, the surface height calculation unit 113 may calculate the minimum value or the optimal value of the elevation of a plurality of target points as the surface height.

FIG. 7 is an exemplary graph in which elevations of a plurality of target points X in an object area 20 are arranged in order according to an embodiment of the present invention.

According to the embodiment shown in Fig. 7, the minimum value among the altitudes of the plurality of target points X in the target area 20 is 2 m, and the optimum is 8 m. According to one embodiment, the surface height calculating unit 113 may calculate 2 m, which is the minimum value among the altitudes of the plurality of target points X, as the height of the surface of the target region 20. According to another embodiment, the ground surface height calculating unit 113 may calculate 8 m corresponding to the optimal elevation among the elevations of the plurality of target points X as the height of the surface of the target area 20.

According to another embodiment of the present invention, the surface height calculation unit 113 calculates a frequency distribution of elevations of elevations of a plurality of target points (X) The height of the surface of the region 20 can be estimated.

8 is an exemplary frequency distribution diagram illustrating frequency distributions for elevation of a plurality of target points X in an object area 20 in accordance with an embodiment of the present invention.

8, the ground surface height calculating unit 113 calculates the height value 4.5 m of the class 1, which is the class having the highest frequency in the frequency distribution of the elevation of the target points X, The height of the surface of the ground.

According to the embodiment, the ground surface height calculating unit 113 may calculate an average value of elevations belonging to a class having the highest frequency in the frequency distribution as the height of the surface of the target area 20. For example, in the embodiment of FIG. 8, the surface height calculating unit 113 may calculate the average value of the elevations belonging to the class 1, which is the class with the highest frequency, and determine the height of the surface of the object area 20.

According to the embodiment, the ground surface height calculating unit 113 can calculate the rank value of the lowest rank in the frequency distribution as the height of the surface of the target area 20. According to the embodiment, the ground surface height calculating unit 113 may calculate an average value of elevations belonging to the lowest rank in the frequency distribution as the height of the surface of the target area 20.

Here, the average value may be an arithmetic average value, a geometric mean value, or a geometric mean value of elevation, and may be a weighted average value in which the elevation of the elevation is applied to the elevation as a weight according to the embodiment.

In the frequency distribution diagram shown in FIG. 8, the size of the class is set to 9 m, but the size of the class is not limited thereto and may be set to be smaller or larger than 9 m. In the frequency distribution diagram shown in FIG. 8, the sizes of the respective classes are set to be the same, but the sizes of the classes constituting the frequency distribution may be set differently according to the embodiment.

The frequency distribution calculating unit 114 may calculate a difference value between the total height and the ground surface height for each of a plurality of target points X. [

Here, the total height of the point is the height of the building reflected in the elevation of the point. According to one embodiment, the total height may represent a value obtained by adding the building height to the elevation. In other words, the total height of the target point is a sum of the elevation of the target point and the height of the building located at the target point. If the target point corresponds to a floor or a surface without building, Can be estimated.

According to one embodiment, the height of the building may be calculated by multiplying the number of the ground floor of the building by a predetermined height. The height multiplied by the number of the ground surface of the building is a height corresponding to one layer of the building, for example, 3 m, but not limited thereto, may be set higher or lower than 3 m.

9 is an exemplary diagram illustrating a process of determining the total height of a target point according to an embodiment of the present invention.

Referring to Fig. 9, the target point 1 is located in a building, and the total height of the target point 1 is 5 m, which is the altitude of the ground, and 12 m of the building height, which is calculated by multiplying 4 layers of the ground floor of the building by 3 m Value of 17 m.

Likewise, the target point 2 is also located in the building, and the total height of the target point 2 is calculated to be 20 m, which is the sum of 11 m of the ground elevation and 9 m of the building height, which is calculated by multiplying 3 m of the ground floor number of the building .

On the other hand, the target point 3 is located on a floor without a building, and the total height of the target point 3 can be calculated as 2 m, which is the elevation of the ground.

10 is an example of a frequency distribution diagram showing a frequency distribution calculated with respect to a difference value between a total height of a plurality of target points X in a target area 20 and a ground surface height according to an embodiment of the present invention.

In the frequency distribution diagram shown in FIG. 10, the difference value between the total height of the target points X in the target area 20 and the height of the ground surface is divided into four classes. However, the number of classes is not limited to this, It may be more or less than four.

. The frequency distribution diagrams shown in FIG. 10 are set such that the sizes of the respective classes are set to be different from each other, but the sizes of the classes constituting the frequency distribution may be set to be the same according to the embodiment.

The parameter value calculation unit 115 may assign the surface roughness to the rank of the frequency distribution calculated with respect to the difference value. According to one embodiment, the parameter value calculation unit 115 may assign the surface roughness according to the rank value of the rank.

For example, referring to FIG. 10, the parameter value calculation unit 115 assigns the surface roughness A having the largest roughness to the rank 4 having the highest rank value, and then, For rank 3, the roughest surface roughness B is assigned, then the second roughest surface roughness C is assigned to rank 2, which has a higher rank value, and the lowest rank value For rank 1, the surface roughness D with the lowest roughness can be assigned.

The parameter value calculation unit 115 may calculate a parameter value of the target area 20 by applying a weight based on the frequency distribution to a parameter value set for each surface roughness.

According to an embodiment of the present invention, the parameter value may be a parameter value that is differently set for each surface ground roughness among parameter values used for design wind speed estimation. For example, the parameter value of wind speed high distribution coefficient (K _zr), branched coefficient (K _zt), turbulence intensity (I _z), wind speed height distribution index (α), based on gyeongdopung height (Z _g) and starting Boundary Layer And a height Z _b .

According to one embodiment, the parameter value calculation unit 115 calculates the relative degrees of each class constituting the frequency distribution, and adds the calculated values by multiplying the parameter values set for each of the ground surface roughnesses by the relative degrees , The parameter value for the area can be calculated.

11 is a table exemplarily showing parameter values set for each surface roughness according to an embodiment of the present invention. 11, the wind speed high distribution coefficient (K _zr), branched coefficient (K _zt), turbulence intensity (I _z), wind speed height distribution index (α), based on gyeongdopung height (Z _g) and starting Boundary Layer The height Z _b may be set to a different value for each surface roughness.

In order to obtain a parameter value for the target area 20, the parameter value calculation unit 115 first calculates the relative frequency of each rank constituting the frequency distribution. For example, referring to the frequency distribution diagram shown in FIG. 10, the parameter value calculation unit 115 may calculate the relative frequency of each class as follows:

Rank 1: Relative frequency 1 = 3/40 = 0.075

Rank 2: Relative frequency 2 = 5/40 = 0.125

Rank 3: Relative frequency 3 = 28/40 = 0.7

Rank 4: Relative frequency 4 = 4/40 = 0.1

Then, the parameter value calculation unit 115 may calculate the parameter value of the target area 20 by multiplying the parameter value set for each of the surface roughnesses by the relative frequency, and adding the obtained values. For example, the wind speed in the region 20 high distribution coefficient (K _zr), branched coefficient (K _zt), turbulence intensity (I _z), wind speed height distribution index (α), based on gyeongdopung height (Z _g) and atmosphere The boundary layer starting height (Z _b ) can be calculated as:

K _zr = 0.58 x 0.1 + 0.81 x 0.7 + 1.0 x 0.125 + 1.13 x 0.075 = 0.83475

K _zt = 1.28 x 0.1 + 1.20 x 0.7 + 1.17 x 0.125 + 1.13 x 0.075 = 1.199

I _z = 0.23 x 0.1 + 0.22 x 0.7 + 0.19 x 0.125 + 0.15 x 0.075 = 0.212

alpha = 0.33 x 0.1 + 0.22 x 0.7 + 0.15 x 0.125 + 0.10 x 0.075 = 0.21325

Z _g = 500 x 0.1 + 400 x 0.7 + 300 x 0.125 + 250 x 0.075 = 386.25

Z _b = 20 x 0.1 + 15 x 0.7 + 10 x 0.125 + 5 x 0.075 = 14.125

The design wind speed calculation unit 116 can calculate the design wind speed for the target area 20 using the parameter values. According to one embodiment, the design wind speed calculation unit 115 calculates or inputs the basic wind speed V ₀ , the wind speed altitude distribution coefficient K _zr , the terrain coefficient K _zt , and the importance coefficient I _w necessary for calculating the design wind speed, It is possible to calculate the wind speed of the wind passing through the target area 20 according to the above-described expression (1).

The target point information obtaining unit 112, the surface height calculating unit 113, the frequency distribution calculating unit 114, the parameter value calculating unit 115, and the design wind speed calculating unit 116 May be configured by a processor, for example, a CPU for executing a design wind speed estimation operation by executing a program for estimating the design wind speed. In addition, a program for estimating the design wind speed may be stored in the storage unit 12, and the design wind speed calculation apparatus 100 may execute the program by loading the program from the storage unit 12. [

The design wind speed estimating apparatus 100 according to an embodiment of the present invention may further include an output unit 14. The output unit 14 may output the calculated design wind speed or the parameter value used in the design wind speed estimation according to an embodiment of the present invention and provide the output 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.

12 is a view for explaining a design wind speed calculation method according to an embodiment of the present invention.

The design wind speed calculation method according to an embodiment of the present invention can obtain elevation information of a target point using data (e.g., position information and elevation information) of a sample point collected from a target area. Then, a frequency distribution is calculated from the data calculated based on the elevation information of the target point and the building information (for example, the height of the building located at the target point), and the parameters used for calculating the design wind speed Value can be calculated.

For example, as shown in FIG. 12, the design wind speed calculation method 300 may include collecting position information and elevation information of a plurality of sample points in a target area 20 (S31) (S32) of generating a plurality of target points (X) in the target point (X) and obtaining elevation information of the target point based on the position information and elevation information of the sample point Calculating a difference value between the total height and the height of the ground surface for each target point, and calculating a frequency distribution of the difference value (S34 (S35) of assigning a surface roughness to the rank of the frequency distribution and applying a weight based on the frequency distribution to a parameter value set for each of the surface roughnesses to calculate a parameter value of the target area, A can using a parameter value comprises the step (S36) for estimating a design wind velocity of the target area 20.

According to one embodiment, the step S31 of collecting the location information and the elevation information of the sample point may include the step of retrieving the geographical information about the object area 20 stored in the storage unit 12. [

According to another embodiment, the collecting step S31 comprises the steps of: connecting to the server 200 providing geographic information about the object area 20; And receiving the geographical information.

According to the embodiment, the collecting step S31 may include receiving geographical information about the target area 20 from the user through the input unit 13. [

According to an embodiment of the present invention, the geographic information for the object area 20 may include at least one of a digital map of the object area and survey data obtained by measuring the object area. 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 an embodiment of the present invention, the step S32 of obtaining the elevation information of the target point X includes the step of creating a target point X on the building located in the object area 20 . According to another embodiment, the step S32 of obtaining the elevation information of the target point X may include the step of generating the target points X at the same intervals in the object area 20, The target points X may be generated nonuniformly at different intervals in the target region 20 according to the target positions. According to the embodiment, the position of the target point X may be input from the user through the input unit 13 and designated.

According to an embodiment of the present invention, the step S32 of obtaining the elevation information of the target point generates the digital elevation model (DEM) of the object area 20 using the position information and the elevation information of the sample point , And calculating an elevation corresponding to the position of the target point (X) in the digital elevation model (DEM) as elevation information of the corresponding target point.

According to another embodiment of the present invention, the step S32 of acquiring the elevation information of the target point calculates the elevation information of the target point X using an interpolation method based on the position information of the sample point and the elevation information . The interpolation method used to estimate the elevation information of the target point X may include, but is not limited to, linear interpolation, non-linear interpolation, or Natural Neighbor interpolation.

The step S33 of calculating the height of the surface of the target area 20 may include calculating a minimum value or an optimal value among elevations of the plurality of target points X. [

According to another embodiment, the step S33 of calculating the height of the ground surface may include calculating a frequency distribution of the elevation of a plurality of target points X, And a step of calculating the number of steps.

According to an embodiment, the step of calculating the height of the ground surface (S33) may include calculating an average value of elevations belonging to the class having the largest frequency.

According to the embodiment, the step S33 of calculating the height of the ground surface may calculate the average value of the lowest rank or the average of the elevations belonging to the lowest rank instead of using the rank with the highest frequency in the frequency distribution.

Here, the average value may be any one of an arithmetic average value, a geometric mean value, and a harmonic mean value of elevation, and may be a weighted average value in which the elevation of the elevation is applied to the elevation in accordance with the embodiment.

The class value or the average value thus calculated is determined as the height of the surface of the object area 20 and can be used for calculating a representative value, which will be described later.

The step (S34) of calculating the frequency distribution may include calculating a difference value between the total height and the ground surface height for each target point, and calculating a frequency distribution for the difference value.

Here, the total height of the target point may be calculated by summing the height of the building located at the target point in the elevation of the target point. Further, the height of the building can be calculated by multiplying the ground floor number of the building by a preset height (for example, 3 m).

The number of classes constituting the frequency distribution of the difference values may coincide with the number of classes of surface roughness. For example, if the surface roughness is classified into four classes as shown in Table 3, the step S34 of calculating the frequency distribution may be performed by dividing the frequency distribution obtained by sequencing the difference values of the plurality of target points X in four ranks Can be calculated. However, according to the embodiment, the ground surface roughness may be divided into a number of classes that is more or less than four, so that the number of classes of the frequency distribution may also be set to more or less than four.

According to an embodiment of the present invention, the step of calculating the parameter value (S35) may include the step of assigning the surface roughness to the rank of the frequency distribution of the difference value. The step of assigning the surface roughness may include assigning the surface roughness to each class according to the class value of the class constituting the frequency distribution. For example, in the step of allocating the surface roughness, the larger the value of the rank, the more rough surface roughness can be assigned.

According to an embodiment of the present invention, the step of calculating the parameter value (S35) includes the steps of: calculating the relative frequency of each class constituting the frequency distribution; and calculating the relative frequency And summing the values obtained by the multiplication.

(K _zr ), the terrain coefficient (K _zt ), the turbulence intensity (I _z ), the wind speed altitude distribution index (?), And the wind velocity altitude distribution index Parameters such as the reference hard wind height Z _g and the atmospheric boundary layer starting height Z _b are set to different values depending on the surface roughness. An embodiment of the present invention can be applied to a case where the parameter values of the target area 20 are uniformly determined on the basis of the ground surface roughness by using information about the heights of a plurality of target points X in the target area 20, Numbers can be provided.

To this end, an embodiment of the present invention allocates surface roughness to each rank of the frequency distribution, multiplies the parameter values set for each surface roughness by the weight of the relative frequency of each class, The parameter can be calculated.

The design wind speed 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.

Herein, the elevation information of the target point is obtained using the position information and the elevation information of the sample point collected from the object area, the frequency distribution is calculated from the data based on the elevation information of the target point and the building information, An apparatus and method for calculating a parameter value for estimating a design wind speed using a frequency distribution has been described.

According to an embodiment of the present invention, a parameter value and a design wind speed suitable for a corresponding area can be calculated based on objective information of a target area, instead of using parameter values uniformly set for each surface roughness. In addition, due to the ground surface roughness determined by the subjective judgment of the designer, the design wind speed can be calculated inappropriately so that the safety and economical efficiency of the building can be prevented from deteriorating.

100: Design wind speed calculation device
10:
111: sample point information collecting unit
112: Target point information obtaining unit
113: Ground surface height calculating section
114: Frequency distribution calculating section
115: Parameter value calculation unit
116: Design wind velocity estimation unit
12:
13:
14: Output section

Claims (21)

A sample point information collecting unit for collecting position information and altitude information of a plurality of sample points in a target area;
A target point information obtaining unit that creates a plurality of target points within the target area and obtains elevation information of the target point based on position information and elevation information of the sample points;
A ground surface height calculating unit for calculating a ground surface height of the target area based on the elevation information of the target point;
A frequency distribution calculating unit for calculating a difference value between the total height of the elevation reflecting the building height and the height of the ground surface for each target point and calculating a frequency distribution of the difference;
A parameter value calculating unit for assigning a surface roughness to the rank of the frequency distribution and calculating a parameter value of the target area by applying a weight based on the frequency distribution to the parameter value set for each of the surface roughnesses; And
A design wind speed calculation unit for calculating a design wind speed of the target area using the calculated parameter value;
And a wind speed estimating device. The method according to claim 1,
The sample point information collecting unit includes:
An electronic map of the subject area; And
Survey data obtained by surveying the target area;
Wherein the position information and the altitude information of the sample point are collected from at least one of the plurality of sample points. The method according to claim 1,
Wherein the target point information obtaining unit comprises:
And creates the target point on a building located within the target area. The method according to claim 1,
Wherein the target point information obtaining unit comprises:
And generates the target points at equal intervals in the target area. The method according to claim 1,
Wherein the target point information obtaining unit comprises:
Generating a digital elevation model (DEM) of the object area using the position information and the elevation information of the sample point,
Wherein the elevation corresponding to the position of the target point in the digital elevation model (DEM) is calculated as elevation information of the target point. The method according to claim 1,
Wherein the target point information obtaining unit comprises:
Wherein the elevation information of the target point is calculated using an interpolation method based on the position information and the elevation information of the sample point. The method according to claim 1,
The ground surface height calculating unit may include:
A minimum value of elevation of the target point;
An optimal elevation of the elevation of the target point;
A rank value of the highest rank in the frequency distribution of the elevation of the target point;
An average value of altitudes belonging to a class having the highest frequency in the frequency distribution of the elevation of the target point;
A rank value of the lowest rank in the frequency distribution of the elevation of the target point; or
An average value of altitudes belonging to the lowest rank in the frequency distribution of the elevation of the target point;
Is calculated as the height of the ground surface. The method according to claim 1,
Wherein the total height is calculated by summing the height of the building on the elevation. 9. The method of claim 8,
Wherein the height of the building is calculated by multiplying the ground floor number of the building by a preset height. The method according to claim 1,
Wherein the parameter value calculation unit comprises:
And assigns the ground surface roughness according to the class value of the class. The method according to claim 1,
Wherein the parameter value comprises at least one of a wind speed altitude distribution coefficient, a terrain coefficient, a turbulence intensity, a wind speed altitude distribution index, a reference rough wind height and an atmospheric boundary layer start height. The method according to claim 1,
Wherein the parameter value calculation unit comprises:
And calculates a relative frequency of each class and adds the calculated values by multiplying the parameter value set for each of the ground surface roughnesses by the relative frequency. Obtaining the elevation information of the target point using the position information and the elevation information of the sample point collected from the object area, calculating the frequency distribution from the data calculated based on the elevation information of the target point and the building information, Calculating a parameter value of the target area by applying a weight to a parameter value set for each of the ground surface roughnesses, and calculating a design wind speed of the target area using the calculated parameter value. Collecting position information and elevation information of a plurality of sample points in the object area;
Generating a plurality of target points within the target area and obtaining elevation information of the target point based on the position information and elevation information of the sample point;
Calculating a height of a surface of the target area based on elevation information of the target point;
Calculating a difference value between the height of the ground surface and the total height of the elevation reflecting the height of the building for each target point and calculating a frequency distribution of the difference;
Calculating a parameter value of the target area by assigning a surface roughness to the rank of the frequency distribution and applying a weight based on the frequency distribution to a parameter value set for each of the surface roughnesses; And
Calculating a design wind speed of the target area using the calculated parameter value;
The method comprising the steps of: 15. The method of claim 14,
Wherein the obtaining of the elevation information of the target point comprises:
And generating the target point on a building located within the target area. 15. The method of claim 14,
Wherein the obtaining of the elevation information of the target point comprises:
And generating the target points at equal intervals in the target area. 15. The method of claim 14,
Wherein the obtaining of the elevation information of the target point comprises:
Generating a digital elevation model (DEM) of the object area using position information and elevation information of the sample point; And
Calculating an elevation corresponding to a position of the target point in the digital elevation model (DEM) as elevation information of the target point;
The method comprising the steps of: 15. The method of claim 14,
Wherein the obtaining of the elevation information of the target point comprises:
Estimating elevation information of the target point using an interpolation method based on position information and elevation information of the sample point;
The method comprising the steps of: 15. The method of claim 14,
Wherein the total height is calculated by summing the height of the building on the elevation. 20. The method of claim 19,
Wherein the height of the building is calculated by multiplying the number of ground layers of the building by a preset height. A computer-readable recording medium,
A recording medium on which a program for executing the method for estimating wind speed according to any one of claims 13 to 20 is recorded.

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