KR102525025B1 - Apparatus for drawing wind rose chart integrated with building cluster ventilation analysis and method thereof - Google Patents

Abstract

The present invention discloses an apparatus and method for creating a wind rose map integrated with air permeability analysis of a building forest. That is, the present invention constructs data related to a building forest around a specific weather observation location where a wind rose map is created, analyzes ventilation characteristics based on the building forest related data related to the specific weather observation location, By integrating the analysis results with the wind rose map and visualizing them, the accuracy and probability of visual interpretation are improved, and through this, a scientific approach to improve the urban canopy model related to building forests and establish spatial planning for the management of urban wind passages can contribute to

Description

Apparatus for drawing wind rose chart integrated with building cluster ventilation analysis and method thereof}

The present invention relates to an apparatus and method for creating a wind rose map in which an analysis of ventilation of a building forest is integrated, and in particular, data related to a building forest around a specific meteorological observation location for which a wind rose map is created is constructed, and the constructed specific An apparatus and method for creating a wind rose map integrated with an air permeability analysis of a building forest that analyzes ventilation characteristics based on data related to a building forest related to a meteorological observation location and integrates the analysis result with a wind rose map to visualize it.

A wind rose is an easy way to show the distribution of wind directions observed at a given point.

The direction of the prevailing wind can be easily determined from the wind rose.

Such a wind rose merely indicates the frequency of occurrence of wind directions by direction and the frequency of wind speed classes by wind direction for a certain period of time at a specific observation point obtained from meteorological observation equipment, and thus it is not possible to sufficiently grasp the environment of the surrounding building forest.

In addition, since the analysis of the urban weather around the observatory is mainly performed by experts who have performed the observation, various approaches based on the wind rose diagram Interpretation is limited.

In addition, cooperation with various experts is required to solve wind-related problems caused by the complex land use of cities. To this end, visual information for interpreting urban winds must be increased and advanced. As the saying goes, there is a limit to showing only the wind rate measured at the station.

Korean Patent Registration No. 10-1919993 [Title: How to prevent the spread of risk in industrial complexes]

An object of the present invention is to build forest-related data around a specific weather observation location where a wind rose map is created, and to analyze ventilation characteristics based on the building forest-related data related to the specific weather observation location constructed above, An object of the present invention is to provide an apparatus and method for creating a wind rose map in which an air permeability analysis of a forest of buildings is integrated and visualized by integrating the analysis result with a wind rose map.

According to an embodiment of the present invention, an apparatus for creating a wind rose map integrated with an air permeability analysis of a building forest includes a communication unit that accesses a server of the National Geographic Information Institute and collects digital map data; And performing a pre-processing function on the collected digital map data, and based on the data related to the surrounding building forest corresponding to the specific meteorological observation location where the wind rose map extracted according to the pre-processing function is created, at the specific weather observation location. It may include a controller that performs a ventilation analysis function for the building forest and generates an integrated wind rose map by integrating the ventilation analysis result of the building forest with the wind rose map.

As an example related to the present invention, the control unit measures key measurements related to analysis of a site to be referred for quantification of ventilation of a nearby building forest centering on a specific weather observation location where a wind rose map is created based on the collected digital map data. It is possible to extract data related to the building forest in the surroundings, which is a preset item.

As an example related to the present invention, the data related to the nearby building forest may include a building area, a building height, and a site area for one or more buildings included in a preset grid centered on the specific weather observation location.

A method for creating a wind rose map incorporating air permeability analysis of building forests according to an embodiment of the present invention includes the steps of connecting to a National Geographic Information Institute server by a communication unit to collect digital map data; performing a pre-processing function on the collected digital map data by a control unit; Performing, by the control unit, a ventilation analysis function for the specific weather observation location based on data related to the surrounding building forest corresponding to the specific weather observation location where the wind rose map extracted according to the performance of the preprocessing function is created ; and generating, by the controller, an integrated wind rose map by integrating the ventilation analysis result of the building forest with the wind rose map.

As an example related to the present invention, the step of performing the ventilation analysis function in the building forest may include setting a unique code for each of a plurality of directions except for a direction in which the size of the front area matches among preset orientations; For each of the plurality of directions, the front area of individual buildings constituting the building forest facing each other based on the wind direction set from the specific weather observation location is calculated, and the front area of each building constituting the calculated building forest is Calculating the total front area of a plurality of building forests by summing them up; calculating a plurality of front area ratios by dividing the calculated total front area of the plurality of buildings in each of the plurality of directions by a plurality of site areas according to each wind direction; arranging ranks in which ventilation is high among the calculated plurality of front area ratios for each of the plurality of directions; and generating a table, which is a result of ventilation analysis of a forest of buildings, including a total front area of a plurality of forests, a plurality of front area ratios, and an air permeability ranking calculated for each of the plurality of directions. can

As an example related to the present invention, the table includes a front area display field for displaying the total front area of the building forest, a front area ratio display field for displaying the front area ratio, a ventilation ranking display field for displaying a ventilation ranking, and a grid number. Grid number display field to display grid area, grid area display field to display grid area, plane area ratio display field to display plane area ratio, average height display field to display average height, maximum height to display maximum height It can be composed of a display field and a standard deviation display field for displaying the standard deviation.

As an example related to the present invention, the step of performing the ventilation analysis function in the building forest is performed in each of a plurality of directions considering the rotation range of the site according to the wind direction using the shape and number of floors of the buildings included in the building layer in the digital map data. A process of generating a plurality of front-side pictures for each; inserting the total front area of the plurality of building forests into the generated plurality of front area pictures; and generating names of the plurality of front-side picture-related files including wind direction and unique identification information of the site.

As an example related to the present invention, the generating of the integrated wind rose map may include generating a background map for integrating and visualizing the ventilation analysis result of the building forest with the wind rose map; inserting a ventilation analysis result of the building forest into the generated background map; generating a wind rose diagram based on wind speed and wind direction frequency associated with the specific weather observation location measured through a weather observation device; And by inserting the generated wind rose diagram into the background map reflecting the ventilation analysis result of the building forest, the wind frequency and the ventilation environment due to the surrounding building forest can be seen together for a specific weather observation location. and a process of generating an integrated wind rose map in which the wind rose map and the wind rose map are integrated.

As an example related to the present invention, the background map is configured in a square shape, a reference circle display area for displaying a wind rose map in the center, a wind rose map display area for adding a wind rose map in the center, and A ventilation analysis result display area for building forests for displaying ventilation analysis results corresponding to positions of a plurality of set wind directions on a planar orthogonal coordinate system may be included.

As an example related to the present invention, the method may further include, by the control unit, collectively constructing a wind rose map including a ventilation analysis result of a forest of buildings and utilizing it for model grid-based evaluation.

The present invention constructs data related to a building forest around a specific weather observation location where a wind rose map is created, analyzes ventilation characteristics based on the building forest related data related to the specific weather observation location, and analyzes the results. by integrating with the wind rose map and visualizing it, it will increase the accuracy and probability of visual interpretation, and through this, it will contribute to the improvement of the urban canopy model related to building forests and the scientific approach to the establishment of spatial planning for the management of the wind passage in the city. There are possible effects.

1 is a block diagram showing the configuration of a wind rose map generating device in which an air permeability analysis of a building forest is integrated according to an embodiment of the present invention.
FIG. 2 is a diagram showing an example of measurement of major items related to analysis of a site to be referred to for quantification of ventilation of a nearby building forest from a specific weather observation location according to an embodiment of the present invention.
3 is a flowchart illustrating a method of creating a wind rose diagram in which an air permeability analysis of a building forest is integrated according to an embodiment of the present invention.
4 is a diagram showing an example for calculating the front area according to an embodiment of the present invention.
5 is a diagram illustrating an example of extracting a picture related to a front area for each wind direction according to an embodiment of the present invention.
6 is a diagram showing an example of a table according to a result of analyzing a forest of surrounding buildings according to an embodiment of the present invention.
7 is a diagram showing an example of a background map in which a ventilation analysis result of a building forest is reflected according to an embodiment of the present invention.
8 is a diagram showing an example of a wind rose diagram according to an embodiment of the present invention.
9 is a diagram showing an example of an integrated wind rose diagram according to an embodiment of the present invention.
10 is a diagram showing an example in which an integrated wind rose map according to an embodiment of the present invention is collectively constructed and configured based on a model grid.
11 is a diagram illustrating an example of utilization based on integrated visualization management of weather observation points in a city according to an embodiment of the present invention.

It should be noted that technical terms used in the present invention are only used to describe specific embodiments and are not intended to limit the present invention. In addition, technical terms used in the present invention should be interpreted in terms commonly understood by those of ordinary skill in the art to which the present invention belongs, unless specifically defined otherwise in the present invention, and are excessively inclusive. It should not be interpreted in a positive sense or in an excessively reduced sense. In addition, when the technical terms used in the present invention are erroneous technical terms that do not accurately express the spirit of the present invention, they should be replaced with technical terms that those skilled in the art can correctly understand. In addition, general terms used in the present invention should be interpreted as defined in advance or according to context, and should not be interpreted in an excessively reduced sense.

Also, singular expressions used in the present invention include plural expressions unless the context clearly dictates otherwise. Terms such as "consisting of" or "comprising" in the present invention should not be construed as necessarily including all of the various elements or steps described in the invention, and some of the elements or steps may not be included. It should be construed that it may, or may further include additional components or steps.

In addition, terms including ordinal numbers such as first and second used in the present invention may be used to describe components, but components should not be limited by the terms. Terms are used only to distinguish one component from another. For example, a first element may be termed a second element, and similarly, a second element may be termed a first element, without departing from the scope of the present invention.

Hereinafter, preferred embodiments according to the present invention will be described in detail with reference to the accompanying drawings, but the same or similar components are given the same reference numerals regardless of reference numerals, and redundant description thereof will be omitted.

In addition, in describing the present invention, if it is determined that a detailed description of a related known technology may obscure the gist of the present invention, the detailed description will be omitted. In addition, it should be noted that the accompanying drawings are only for easily understanding the spirit of the present invention, and should not be construed as limiting the spirit of the present invention by the accompanying drawings.

1 is a block diagram showing the configuration of an apparatus 100 for creating a wind rose map in which an air permeability analysis of a building forest is integrated according to an embodiment of the present invention.

As shown in FIG. 1, the wind rose map generating device 100 in which the analysis of the ventilation of the building forest is integrated includes a communication unit 110, a storage unit 120, a display unit 130, an audio output unit 140, and a control unit 150. ) is composed of Not all of the components of the wind rose drawing device 100 in which the air permeability analysis of the building forest is integrated shown in FIG. The integrated wind rose map creation device 100 may be implemented, or the wind rose map creation device 100 in which the air permeability analysis of the building forest is integrated may be implemented with fewer components.

The device 100 for creating a wind rose map integrated with the air permeability analysis of the building forest is a smart phone, a portable terminal, a mobile terminal, a foldable terminal, a personal information terminal ( Personal Digital Assistant: PDA), PMP (Portable Multimedia Player) terminal, Telematics terminal, Navigation terminal, Personal Computer, Notebook PC, Slate PC, Tablet PC , ultrabook, wearable device (including, for example, a watch type terminal (Smartwatch), a glass type terminal (Smart Glass), HMD (Head Mounted Display), etc.), Wibro terminal, IPTV ( It can be applied to various terminals such as Internet Protocol Television) terminals, smart TVs, digital broadcasting terminals, AVN (Audio Video Navigation) terminals, A / V (Audio / Video) systems, flexible terminals, digital signage devices, etc. . At this time, the wind rose map making device 100 integrated with the analysis of the air permeability of the building forest may be a terminal possessed by a user (or manager) who intends to perform the air permeability analysis of the building forest by region.

In addition, the device 100 for creating a wind rose map in which the air permeability analysis of the building forest is integrated communicates with a server (not shown) or the like.

Here, the server may be implemented in the form of a web server, database server, proxy server, and the like. In addition, one or more of a network load balancing mechanism and various software enabling the corresponding server to operate on the Internet or other networks may be installed in the server, and through this, it may be implemented as a computerized system. Also, the network can be an http network, a private line, an intranet or any other network. Furthermore, the connection between the wind rose map making device 100 in which the air permeability analysis of the building forest is integrated and the server may be connected through a secure network to prevent data from being attacked by any hacker or other third party. In addition, the server may include a plurality of database servers, and these database servers may be implemented in a manner that is separately connected to the server through any type of network connection including a distributed database server architecture.

The communication unit 110 communicates with any internal component or at least one external terminal through a wired/wireless communication network. In this case, the external arbitrary terminal may include a server (not shown) and the like. Here, wireless Internet technologies include Wireless LAN (WLAN), DLNA (Digital Living Network Alliance), Wireless Broadband (Wibro), WiMAX (World Interoperability for Microwave Access: Wimax), HSDPA (High Speed Downlink Packet Access) ), High Speed Uplink Packet Access (HSUPA), IEEE 802.16, Long Term Evolution (LTE), Long Term Evolution-Advanced (LTE-A), Wireless Mobile Broadband Service (WMBS), etc. , and the communication unit 110 transmits and receives data according to at least one wireless Internet technology within a range including Internet technologies not listed above. In addition, short-range communication technologies include Bluetooth, Radio Frequency Identification (RFID), Infrared Data Association (IrDA), Ultra Wideband (UWB), ZigBee, and Near Field Communication (NFC). , Ultra Sound Communication (USC), Visible Light Communication (VLC), Wi-Fi, Wi-Fi Direct, and the like may be included. In addition, wired communication technologies may include power line communication (PLC), USB communication, Ethernet, serial communication, optical/coaxial cables, and the like.

In addition, the communication unit 110 may mutually transmit information with an arbitrary terminal through a Universal Serial Bus (USB).

In addition, the communication unit 110 complies with technical standards or communication methods for mobile communication (eg, Global System for Mobile communication (GSM), Code Division Multi Access (CDMA), Code Division Multi Access 2000 (CDMA2000), EV) -DO(Enhanced Voice-Data Optimized or Enhanced Voice-Data Only), WCDMA(Wideband CDMA), HSDPA(High Speed Downlink Packet Access), HSUPA(High Speed Uplink Packet Access), LTE(Long Term Evolution), LTE-A (Long Term Evolution-Advanced), etc.) to transmit and receive radio signals with the base station and the server on the mobile communication network.

In addition, the communication unit 110 collects (or receives) digital map data from the National Geographic Information Institute server (not shown) under the control of the control unit 150 .

The storage unit 120 stores various user interfaces (UI), graphic user interfaces (GUI), and the like.

In addition, the storage unit 120 stores data and programs necessary for the operation of the wind rose map generating device 100 integrated with the analysis of the air permeability of the building forest.

That is, the storage unit 120 includes a plurality of application programs (applications) running in the wind rose diagram drawing device 100 in which the analysis of the ventilation of the building forest is integrated, and the wind in which the analysis of the ventilation of the building forest is integrated. Data and instructions for operating the rose diagram drawing device 100 may be stored. At least some of these application programs may be downloaded from an external server through wireless communication. In addition, at least some of these applications will be present on the wind rose map creation device 100 integrated with the ventilation analysis of the building forest from the time of shipment for the basic function of the wind rose drawing device 100 integrated with the analysis of the air permeability of the building forest. can On the other hand, the application program is stored in the storage unit 120, installed in the wind rose drawing device 100 in which the analysis of the ventilation of the building forest is integrated, and the wind rose in which the analysis of the ventilation of the building forest is integrated by the control unit 150 It can be driven to perform the operation (or function) of the map preparation device 100 .

In addition, the storage unit 120 may be a flash memory type, a hard disk type, a multimedia card micro type, or a card type memory (eg, SD or XD). memory, etc.), magnetic memory, magnetic disk, optical disk, RAM (Random Access Memory: RAM), SRAM (Static Random Access Memory), ROM (Read-Only Memory: ROM), EEPROM (Electrically Erasable Programmable Read-Only Memory), It may include at least one storage medium of PROM (Programmable Read-Only Memory). In addition, the wind rose map creation device 100 integrated with the analysis of the air permeability of the building forest operates a web storage that performs the storage function of the storage unit 120 on the Internet, or is related to the web storage. it might work.

In addition, the storage unit 120 stores digital map data collected (or received) through the communication unit 110 under the control of the control unit 150 .

The display unit (or display unit) 130 may display various contents such as various menu screens using a user interface and/or a graphic user interface stored in the storage unit 120 under the control of the control unit 150. there is. Here, the content displayed on the display unit 130 includes various text or image data (including various information data) and a menu screen including data such as icons, list menus, and combo boxes. Also, the display unit 130 may be a touch screen.

In addition, the display unit 130 may include a liquid crystal display (LCD), a thin film transistor-liquid crystal display (TFT LCD), an organic light-emitting diode (OLED), and a flexible display. (Flexible Display), a three-dimensional display (3D Display), e-ink display (e-ink display), it may include at least one of LED (Light Emitting Diode).

In addition, the display unit 130 displays digital map data collected (or received) through the communication unit 110 under the control of the control unit 150 .

The audio output unit 140 outputs audio information included in a signal that has been subjected to predetermined signal processing by the control unit 150 . Here, the audio output unit 140 may include a receiver, a speaker, a buzzer, and the like.

In addition, the voice output unit 140 outputs a guide voice generated by the control unit 150 .

In addition, the audio output unit 140 outputs audio information (or sound information) corresponding to the digital map data collected (or received) through the communication unit 110 under the control of the control unit 150. .

The controller (or microcontroller unit (MCU) 150) executes overall control functions of the wind rose map generating device 100 in which the air permeability analysis of the building forest is integrated.

In addition, the control unit 150 executes overall control functions of the wind rose map generating device 100 integrated with air permeability analysis in the building forest by using programs and data stored in the storage unit 120 . The controller 150 may include RAM, ROM, CPU, GPU, and a bus, and the RAM, ROM, CPU, and GPU may be connected to each other through a bus. The CPU may access the storage unit 120 and perform booting using the O/S stored in the storage unit 120, and use various programs, contents, data, etc. stored in the storage unit 120. It can perform various operations.

In addition, the control unit 150 interworks with the server, and through a dedicated app and / or website provided by the server, the ventilation analysis function of the building forest, the integrated wind that integrates the ventilation analysis result of the building forest and the wind rose diagram. A user registers as a member to receive a rose map creation function, an integrated wind rose map utilization function, and the like, and personal information is registered in the server. At this time, the personal information includes ID, e-mail address, password (or password), name, gender, date of birth, contact information (or phone number), address, and the like.

In addition, the control unit 150 may sign up as a user in the server using SNS account information or mobile messenger account information to which the user of the wind rose drawing device 100 integrated with the analysis of the ventilation of the corresponding building forest is registered. . Here, the SNS account may be information related to Facebook, Twitter, Kakao Story, Naver, PAYCO, and the like. In addition, the mobile messenger account is information related to KakaoTalk, line, viber, wechat, whatsapp, telegram, snapchat, etc. can

In addition, when performing the member sign-up procedure, the control unit 150 must complete an authentication function through a user authentication means (eg, including a mobile phone, credit card, i-PIN, etc.) to normally complete the member sign-up procedure for the server. there is.

In addition, after membership registration is completed, the control unit 150 integrates a dedicated app (or application/application program/specific app) provided from the server with the ventilation analysis of the building forest in order to use the service provided by the server. The wind rose is also installed in the making device 100. In this case, the dedicated app may be an app for performing a function of analyzing ventilation of a building forest, a function of creating an integrated wind rose map in which a ventilation analysis result of a building forest and a wind rose map are integrated, and a function of using an integrated wind rose map.

In addition, the control unit 150 executes a dedicated app pre-installed in the wind rose drawing device 100 in which the analysis of ventilation of the building forest is integrated, and displays an app execution result screen according to the execution of the dedicated app on the display unit 130. do. At this time, the app execution result screen shows the utilization status of the ventilation analysis menu (or item/button) for performing the ventilation analysis function of the building forest, the integrated wind rose map creation menu for creating the integrated wind rose map, and the integrated wind rose map. It includes a utilization menu for checking, a setting menu for setting dedicated app functions, and the like. Here, the control unit 150 registers as a member of the server providing the dedicated app, and performs a login procedure when the dedicated app is executed using an ID and password according to membership registration, a barcode or QR code including the ID, and the like. By performing, one or more functions of the dedicated app (including, for example, building forest ventilation analysis function, integrated wind rose map creation function that integrates building forest ventilation analysis results and wind rose map, integrated wind rose map utilization function, etc.) can be done

The technology for creating a wind rose chart described in the present invention is a wind direction appearance frequency and wind direction by direction for a certain period of time at a specific weather observation location obtained from a weather observation device (not shown) capable of measuring wind direction and wind speed. It is a technique to graphically represent wind speed class frequencies.

In addition, the wind rose uses 8 directions or 16 directions such as north wind (N), north northeast wind (NNE), and northeast wind (NE) as basic directions, but may be subdivided into 32 directions. Normally, a north wind blows from a direction of 0° or 360°, an east wind of 90°, a south wind of 180°, and a west wind of 270°.

In addition, the percentage (%) of the frequency of wind appearance is displayed as the length of the bearing line on the azimuth plate corresponding to each wind direction, and the frequency of appearance of calm (calm) is separately displayed in the center or next to the graph.

In addition, the control unit 150 collects (or receives) digital map data from the National Geographic Information Institute server (not shown) through the communication unit 110 . Here, the digital map data includes a building layer (for example, N3A_B0010000) of a 1:50,000 digital map 2.0 data. In this case, the building layer includes the shape number of floors (GRO_FLO_CO) of Korean buildings (shape features), and the like.

In addition, the quantified building forest shape analysis technology is a technology that quantitatively displays the three-dimensional shape of individual buildings (or buildings) through horizontal or vertical measurement. Among them, the building forest ventilation analysis technology examines the relationship between the data observed for wind speed and the data measured in relation to the shape of the building forest to quantify the relationship between the shape of the building forest and the ventilation that affects the wind speed. It is a skill.

In addition, the controller 150 performs a pre-processing function (or pre-processing process) on the collected digital map data.

That is, the control unit 150, based on the collected digital map data, controls the key measurement item related to the analysis of the site to be referred for quantification of the ventilation of the surrounding building forest centering on the specific meteorological observation location where the wind rose map is created. Extract data related to the building forest around the set area.

At this time, as shown in FIG. 2 , the control unit 150 first determines the wind direction 220 blowing into the building forest in order to measure the air permeability of the building forest. In a normal case, the control unit 150 determines the main wind direction as the wind direction, and in the stage where the main wind direction is not determined, all directions are reviewed to determine the main wind direction. Here, the surrounding building forest related data (or the surrounding building forest related data from the specific weather observation location) is the building area 230, building height ( 240), site area 250, and the like. At this time, a lattice structure (eg, 100 m × 100 m, etc.) of a predetermined size is considered for the surrounding building forest centered on the specific weather observation location 210 . In addition, the building area 230 includes a building front area 231 indicating the area of the front of the building perpendicular to the wind direction, a building floor area 232 indicating the area of the building plane, and the like. In addition, the building height 240 represents the height of the building (eg, including the highest floor height and average height). In addition, the site area 250 is measured (or calculated) in consideration of the width 251 of the site facing from the wind direction and the depth 252 of the site. Here, if the site has a rectangular shape with respect to the wind direction, the site area is a value obtained by multiplying the width of the site by the depth of the site. In addition, when the site has a shape other than a rectangle, the area of the site is calculated according to an area calculation method based on a general coordinate system.

In addition, the control unit 150 calculates (or sets) the total area of the aggregated floor area of individual buildings as the area of the building forest in the site, as the building forest is composed of a plurality of buildings in most of the building forest analysis for ventilation analysis. /Process), and calculate (or set/process) a value obtained by dividing the total volume of the volumes of individual buildings by the total area as the height of the forest of buildings in the site (or the average height of the forest of buildings) 260.

In this way, the control unit 150 extracts data related to surrounding building forests including building area, building height, site area, etc. around a specific meteorological observation location where a wind rose map is created from the collected digital map data.

In addition, the control unit 150 performs a ventilation analysis function of a building forest for a specific weather observation location based on data related to a nearby building forest corresponding to a specific weather observation location where a wind rose map extracted according to the performance of the preprocessing function is created ( or building forest ventilation analysis process).

That is, the control unit 150 calculates the front area of each building constituting the forest of buildings facing each other based on the wind direction set from the specific weather observation location, and calculates the calculated front area of each building constituting the forest of buildings. Calculate the frontal area of all buildings (or the total frontal area/floor area of a forest of buildings) by summing (or counting) Here, the front area (or the front area of a building/building) is an important criterion for evaluating ventilation by a forest of buildings around the specific weather observation location, and is the area of the elevation of the building, but the area of the side constituting the actual building. It is calculated as the projected area perpendicular to the wind direction. If there is only one building in the site, the area projected to the elevation of the building in the wind direction becomes the front area of the building.

In addition, the elevation area of a building is the area where the building stands facing the wind, and is calculated by multiplying the width of the building facing the wind direction by the height estimated from the number of floors of the building.

For example, if there is a 10-story building and the height of each floor of the building is set to be 3 m, the height is 30 m, and the elevation area of the building is obtained by multiplying the height (30 m) by the width of the elevation facing the wind direction. is the value

Usually, a forest of buildings is composed of a plurality of buildings, and the controller 150 calculates the front area of all buildings in the forest of buildings by summing all the front areas of buildings corresponding to elevations in the wind direction. At this time, in the process of projecting several buildings, the controller 150 may overlap the front area of the buildings. Since this overlapping front area affects the ventilation characteristics, the control unit 150 sums up all the overlaps to determine the level of the corresponding building. Calculate the total front area. Here, the frontal area of the building is the area of the building facing the wind, and is used as the same concept as the elevational area of the building.

In addition, the controller 150 calculates the front area ratio (or elevation area ratio) by dividing the calculated front area of all buildings (or the total front area/floor area of the forest of buildings) by the calculated site area.

Next, the controller 150 sets (or assigns) a unique code (or unique identification code/specific number) to each of the remaining 8 directions, excluding directions in which the size of the front area matches among the preset 16 orientations. Here, the 16 azimuths are north (N), north-northeast (NNE), north east (NE), east-northeast (EEN), east (E), east-south-east (east- southeast: EES), south east: SE, south-southeast: SSE, south: S, south-southwest: SSW, south west: SW, west-southwest It includes southwest: WWS), west: W, west-northwest: WWN, north west: NW, and north-northwest: NNW. Among them, the controller 150 controls the north wind and south wind, north northwest wind and south southeast wind, northwest wind and southeast wind, west northwest wind and southeast wind, west wind and east wind, west southwest wind and northeast wind, southwest wind and northeast wind, which are directions in which the size of the front area coincides. And, for the south-southwest wind and the north-northeast wind, eight directions (for example, north wind, north-northwest wind, northwest wind, northwest wind, west wind, southwest wind, southwest wind, and south-southwest wind), a code to h code that is a preset unique code set each

That is, since the wind direction is flexible, the control unit 150 determines the wind direction survey range and investigates only the minimum direction for which the front area change survey for each wind direction is effective.

For example, if the ventilation analysis range of the building forest in the site is set to 16 directions, the front area of the symmetrical wind direction is the same (for example, the front area of the north wind and the south wind are the same), so 8 directions except for one direction The front-to-front ratio may vary.

In this case, the control unit 150 sets the a code to the north or south wind direction based on the north, sets the b code to the north northwest or south southeast wind direction, sets the c code to the northwest or southeast wind direction, and sets the northwest wind direction. Or set the d code for the southeast or east direction, set the e code for the westerly or east wind direction, set the f code for the southwest or northeast wind direction, set the g code for the southwest or northeast direction, or set the g code for the southwest or northeast wind direction. Set the h code for the northeast wind direction.

In the embodiment of the present invention, the description is based on 16 orientations, but is not limited thereto, and the technical concepts of the present invention may be applied to 4 orientations, 8 orientations, 32 orientations, etc. according to the designer's design.

In addition, the control unit 150 calculates (or considers) each front area according to the rotation range of the site (eg, including a square) for the forests of buildings applied to the elevation area calculation for each wind direction.

Accordingly, the controller 150 generates (or draws/draws/ make/construct).

In addition, the control unit 150 records (or applies / reflects / adds / inserts / mark).

That is, the control unit 150 changes the frontal area of the building facing each wind direction (for example, the height does not change, but the width of the building from the wind direction changes), so that the numerical value of the frontal area according to the projection can be confirmed. is inserted into each front-side figure.

In addition, the control unit 150 includes the generated (or manufactured / configured) eight front-side picture-related files to include wind direction (or unique code), unique identification information (or site ID) of a preset site, and the like. Generates the name (or file name) of

In addition, the control unit 150 stores eight front-side pictures of corresponding file names in the storage unit 120.

Next, the control unit 150 refers to the a-code to h-code assigned to each of the eight directions, and quantifies the front area (or the total front area of the forest of buildings) by measuring the shape of each building constituting the forest of buildings. , the front area ratio, and the ranking of the highest permeability among the eight directions, and record these in records in individual tables pertaining to the site. Here, the air permeability may be relatively better as the front area ratio is lower than when the front area ratio is high. In addition, the table includes a field for displaying (or recording) front area, front area ratio, ventilation ranking, etc. (eg, including front area display field, front area display field, ventilation ranking display field, etc.), grid number, grid Fields for displaying area, area ratio, average height, maximum height, standard deviation, etc. including a display field, etc.) and the like. At this time, the control unit 150 checks a grid number including a specific meteorological observation location where the wind rose map is created from the digital map data, and displays the checked grid number in a grid number display field in the table, The grid area between corresponding grids is checked from the digital map data, the checked grid area is displayed in the grid area display field in the table, and the building included in the grid related to the specific weather observation location where the wind rose map is created Check (or calculate) the floor area ratio for the area, display the checked floor area ratio in the plane area display field in the table, and check the maximum height of the building included in the grid related to the specific weather observation location where the wind rose map is created and displays the checked maximum height in the maximum height display field in the table, checks (or calculates) the standard deviation for the heights between buildings, and displays the checked standard deviation in the standard deviation display field in the table. can

That is, the control unit 150 may record the calculated front area for each wind direction code (or the total front area of the building forest) and the front area ratio in the table for recording the property related to the site in two directions for each of the eight directions. Fields (including, for example, F_area corresponding to the front area, LAMB_F corresponding to the front area ratio, etc.) are added to the table, and the front area and front area ratio for the calculated 8 directions are added to the table. record each in

In addition, the control unit 150 adds a ventilation ranking field for recording the ventilation ranking to the table, and sorts the eight front ratios in order from the lowest to the highest (or ascending) front area ratio for each wind direction, , The sorted front area ratios are respectively recorded in the ventilation ranking field in the table in order of the wind direction with the lowest.

In this way, the control unit 150 performs a function of analyzing ventilation of building forests by using data related to surrounding building forests corresponding to a specific meteorological observation location where the wind rose map extracted according to the preprocessing function is created, and ventilation of building forests is performed. A ventilation analysis result (or the above table) is generated according to the execution of the analysis function.

In addition, the control unit 150 integrates the ventilation analysis result of the building forest (or the ventilation analysis map of the surrounding building forest) with the wind rose diagram and visualizes it.

That is, the controller 150 generates (or writes/designs/composes/manufactures) a layout map for integrating and visualizing the ventilation analysis result of the building forest with the wind rose map. Here, the background map is formed in a square shape, a reference circle display area for displaying the wind rose map accurately in the center, a wind rose map display area for adding a wind rose map to the center, and eight preset wind directions. It includes a ventilation analysis result display area for building forests for displaying the ventilation analysis results (including, for example, ranking of front area ratio, front area ratio, etc.) corresponding to the location of the building forest ventilation analysis result on a plane Cartesian coordinate system.

In addition, the control unit 150 inserts (or adds/applies/reflects/displays) the ventilation analysis result of the building forest in the created (or created/designed/constructed/manufactured) background map.

That is, the control unit 150 adds a front area ratio ranking and a front area ratio for each preset wind direction to the ventilation analysis result display area of the building forest formed along the outer circumferential surface of the generated background map.

In addition, the control unit 150 generates a wind rose diagram based on the wind speed, wind direction frequency, etc. related to the specific weather observation location measured by a weather observation device (not shown) (or received from the weather observation device) ( or written). At this time, the control unit 150 may download (or receive/receive) a wind rose map related to the specific weather observation location from the Korea Meteorological Administration server (not shown) through the communication unit 110 .

In addition, the control unit 150 inserts (or adds/applies/reflects/displays) the generated wind rose map to the background map reflecting the ventilation analysis result of the building forest, and determines the wind frequency and surroundings for a specific meteorological observation location. Create (or create/construct) an integrated wind rose map (or integrated chart) that integrates the results of air permeability analysis of the building forest and the wind rose map, which can view the ventilation environment caused by the building forest.

In addition, the control unit 150 collectively builds a wind rose map (or the integrated wind rose map/integrated chart) including the result of ventilation analysis in the building forest and uses it for model grid-based evaluation.

That is, the control unit 150 analyzes the spatial structure and wind relationship of individual grids of the numerical model composed of matrices in detail to improve the urban canopy model for improving the accuracy of urban weather forecasting. A plurality of integrated wind rose maps are respectively generated (or created) for each of a plurality of meteorological observation positions at which wind rose maps are created.

In addition, the control unit 150 applies the generated plurality of integrated wind rose maps for each of the plurality of weather observation locations (or integrated wind rose map for each of the plurality of grids) to individual grids of the numerical model composed of the matrix and displays them.

In addition, the control unit 150 describes the wind environment of a city or small town by selecting several important points to be used in urban planning such as a district unit plan reflecting the location of each weather observation network to be densely built in each city. Visualize the ventilation environment in the area where

Through this, since the wind direction is different for each important point and the surrounding building forest environment is different, it is possible to comprehensively solve the ventilation environment of a town or city by checking them together.

The ventilation analysis function of the building forest described in the embodiment of the present invention, the function of creating an integrated wind rose map integrating the ventilation analysis result of the building forest and the wind rose map, and the integrated wind rose map utilization function, etc. It may be performed through a dedicated app installed on the rose map creation device 100 or through a website provided by the server.

In this way, as the city's building forest spreads horizontally and rises vertically, the natural wind that moves from the suburbs to the center of the city collides with the building forest, breaks and changes direction, and depending on the place, strong winds arise like building winds. This stagnant distortion occurs, and in order to solve various urban wind-related problems such as fine dust and heat waves, predictions can be made through detailed investigation and analysis of wind-related information in the city.

Also, in this way, the wind rose map can be used to describe and evaluate the current wind conditions in the process of pre-evaluating the impact of various land uses that change the city's building forest through environmental impact assessment.

In addition, the wind in the city is measured through a fixed weather station (not shown), an automated weather station (not shown), and a mobile station (not shown) at a specific location, and a wind rose map is being created through this, but the wind rose map is being created. It is not possible to fully understand the environment of the surrounding building forest with only the rose map, and the environment of the surrounding building forest can be grasped through the integrated wind rose map according to the embodiment of the present invention.

In this way, building forest-related data around the specific meteorological observation location where the wind rose map is created is established, ventilation characteristics are analyzed based on the building forest-related data related to the specific meteorological observation location constructed above, and the analysis results can be visualized by integrating with the wind rose diagram.

Hereinafter, a method for creating a wind rose map in which the air permeability analysis of building forests is integrated according to the present invention will be described in detail with reference to FIGS. 1 to 11 .

3 is a flowchart illustrating a method of creating a wind rose diagram in which an air permeability analysis of a building forest is integrated according to an embodiment of the present invention.

First, the control unit 150 collects (or receives) digital map data from the National Geographic Information Institute server (not shown) through the communication unit 110 . Here, the digital map data includes a building layer (for example, N3A_B0010000) of a 1:50,000 digital map 2.0 data. In this case, the building layer includes the shape number of floors (GRO_FLO_CO) of Korean buildings (shape features), and the like.

For example, the first control unit 150 accesses the National Geographic Information Institute server through the first communication unit 110, searches for digital map 2.0 data of 1:50,000 in the connected National Geographic Information Institute server, and retrieves the searched 1 : Collect (or download) 50,000 digital map 2.0 data (S310).

Thereafter, the controller 150 performs a preprocessing function (or preprocessing process) on the collected digital map data.

That is, the control unit 150, based on the collected digital map data, controls the key measurement item related to the analysis of the site to be referred for quantification of the ventilation of the surrounding building forest centering on the specific meteorological observation location where the wind rose map is created. Extract data related to the building forest around the set area.

At this time, as shown in FIG. 2 , the control unit 150 first determines the wind direction 220 blowing into the building forest in order to measure the air permeability of the building forest. In a normal case, the control unit 150 determines the main wind direction as the wind direction, and in the stage where the main wind direction is not determined, all directions are reviewed to determine the main wind direction. Here, the surrounding building forest related data (or the surrounding building forest related data from the specific weather observation location) is the building area 230, building height ( 240), site area 250, and the like. At this time, a lattice structure (eg, 100 m × 100 m, etc.) of a predetermined size is considered for the surrounding building forest centered on the specific weather observation location 210 . In addition, the building area 230 includes a building front area 231 indicating the area of the front of the building perpendicular to the wind direction, a building floor area 232 indicating the area of the building plane, and the like. In addition, the building height 240 represents the height of the building (eg, including the highest floor height and average height). In addition, the site area 250 is measured (or calculated) in consideration of the width 251 of the site facing from the wind direction and the depth 252 of the site. Here, if the site has a rectangular shape with respect to the wind direction, the site area is a value obtained by multiplying the width of the site by the depth of the site. In addition, when the site has a shape other than a rectangle, the area of the site is calculated according to an area calculation method based on a general coordinate system.

In addition, the control unit 150 calculates (or sets) the total area of the aggregated floor area of individual buildings as the area of the building forest in the site, as the building forest is composed of a plurality of buildings in most of the building forest analysis for ventilation analysis. /Process), and calculate (or set/process) a value obtained by dividing the total volume of the volumes of individual buildings by the total area as the height of the forest of buildings in the site (or the average height of the forest of buildings) 260.

In this way, the control unit 150 extracts data related to surrounding building forests including building area, building height, site area, etc. around a specific meteorological observation location where a wind rose map is created from the collected digital map data.

For example, the first control unit is a building forest located in a preset grid including the first weather observation location centered on the first weather observation location where a wind rose map is created from the collected digital map 2.0 data of 1:50,000. Data related to the 1st surrounding building forest, including the building front area, building height, site area, etc., are extracted (S320).

Thereafter, the control unit 150 performs a ventilation analysis function of a building forest for a specific weather observation location based on data related to the surrounding building forest corresponding to the specific weather observation location where the wind rose map extracted according to the performance of the preprocessing function is created ( or building forest ventilation analysis process).

That is, the control unit 150 calculates the front area of each building constituting the forest of buildings facing each other based on the wind direction set from the specific weather observation location, and calculates the calculated front area of each building constituting the forest of buildings. Calculate the frontal area of all buildings (or the total frontal area/floor area of a forest of buildings) by summing (or counting) Here, the front area (or the front area of a building/building) is an important criterion for evaluating ventilation by a forest of buildings around the specific weather observation location, and is the area of the elevation of the building, but the area of the side constituting the actual building. It is calculated as the projected area perpendicular to the wind direction. If there is only one building in the site, the area projected to the elevation of the building in the wind direction becomes the front area of the building.

In addition, the elevation area of a building is the area where the building stands facing the wind, and is calculated by multiplying the width of the building facing the wind direction by the height estimated from the number of floors of the building.

Usually, a forest of buildings is composed of a plurality of buildings, and the controller 150 calculates the front area of all buildings in the forest of buildings by summing all the front areas of buildings corresponding to elevations in the wind direction. At this time, in the process of projecting several buildings, the controller 150 may overlap the front area of the buildings. Since this overlapping front area affects the ventilation characteristics, the control unit 150 sums up all the overlaps to determine the level of the corresponding building. Calculate the total front area. Here, the frontal area of the building is the area of the building facing the wind, and is used as the same concept as the elevational area of the building.

In addition, the controller 150 calculates the front area ratio (or elevation area ratio) by dividing the calculated front area of all buildings (or the total front area/floor area of the forest of buildings) by the calculated site area.

Next, the controller 150 sets (or assigns) a unique code (or unique identification code/specific number) to each of the remaining 8 directions, excluding directions in which the size of the front area matches among the preset 16 orientations. Here, the 16 directions are north (N), north-northeast (NNE), northeast (NE), northeast-east (EEN), east (E), southeast-east (EES), southeast (SE), south-southeast (SSE), south (S) , south-southwest (SSW), south-west (SW), south-west (WWS), west (W), north-west (WWN), north-west (NW), and north-north-west (NNW). Among them, the controller 150 controls the north wind and south wind, north northwest wind and south southeast wind, northwest wind and southeast wind, west northwest wind and southeast wind, west wind and east wind, west southwest wind and northeast wind, southwest wind and northeast wind, which are directions in which the size of the front area coincides. And, for the south-southwest wind and the north-northeast wind, eight directions (for example, north wind, north-northwest wind, northwest wind, northwest wind, west wind, southwest wind, southwest wind, and south-southwest wind), a code to h code that is a preset unique code set each

That is, since the wind direction is flexible, the control unit 150 determines the wind direction survey range and investigates only the minimum direction for which the front area change survey for each wind direction is effective.

For example, if the ventilation analysis range of the building forest in the site is set to 16 directions, the front area of the symmetrical wind direction is the same (for example, the front area of the north wind and the south wind are the same), so 8 directions except for one direction The front-to-front ratio may vary.

In this case, the control unit 150 sets the a code to the north or south wind direction based on the north, sets the b code to the north northwest or south southeast wind direction, sets the c code to the northwest or southeast wind direction, and sets the northwest wind direction. Or set the d code for the southeast or east direction, set the e code for the westerly or east wind direction, set the f code for the southwest or northeast wind direction, set the g code for the southwest or northeast direction, or set the g code for the southwest or northeast wind direction. Set the h code for the northeast wind direction.

In addition, the control unit 150 calculates (or considers) each front area according to the rotation range of the site (eg, including a square) for the forests of buildings applied to the elevation area calculation for each wind direction.

Accordingly, the controller 150 generates (or draws/draws/ make/construct).

In addition, the control unit 150 records (or applies / reflects / adds / inserts / mark).

That is, the control unit 150 changes the frontal area of the building facing each wind direction (for example, the height does not change, but the width of the building from the wind direction changes), so that the numerical value of the frontal area according to the projection can be confirmed. is inserted into each front-side figure.

In addition, the control unit 150 generates names (or file names) of the created (or manufactured/composed) eight front-side picture-related files to include the wind direction (or unique code), site ID, and the like.

In addition, the control unit 150 stores eight front-side pictures of corresponding file names in the storage unit 120.

In addition, the control unit 150 refers to the a code to h code assigned to each of the eight directions, the front area quantified through the measurement of the shape of each building constituting the building forest (or the total front area of the building forest), List the face ratio and the highest ventilation rank among the eight directions, and record this in the records of the individual tables pertaining to the site. Here, the air permeability may be relatively better as the front area ratio is lower than when the front area ratio is high. In addition, in addition to fields for displaying (or recording) front area, front area ratio, ventilation ranking, etc., the table includes fields for displaying grid number, grid area, plane area ratio, average height, maximum height, standard deviation, etc. can be configured.

That is, the control unit 150 may record the calculated front area for each wind direction code (or the total front area of the building forest) and the front area ratio in the table for recording the property related to the site in two directions for each of the eight directions. Fields (including, for example, F_area corresponding to the front area, LAMB_F corresponding to the front area ratio, etc.) are added to the table, and the front area and front area ratio for the calculated 8 directions are added to the table. record each in

In addition, the control unit 150 adds a ventilation ranking field for recording the ventilation ranking to the table, and sorts the eight front ratios in order from the lowest to the highest (or ascending) front area ratio for each wind direction, , The sorted front area ratios are respectively recorded in the ventilation ranking field in the table in order of the wind direction with the lowest.

In this way, the control unit 150 performs a function of analyzing ventilation of building forests by using data related to surrounding building forests corresponding to a specific meteorological observation location where the wind rose map extracted according to the preprocessing function is created, and ventilation of building forests is performed. A ventilation analysis result (or the above table) is generated according to the execution of the analysis function.

For example, as shown in FIG. 4 , the first control unit controls individual buildings in the forest of buildings facing each other based on the wind direction 410 set from the first weather observation location with respect to a forest of buildings composed of a plurality of buildings. The total front area of the first building forest, which is the front area of all the buildings, is calculated by calculating the front area and summing up the front area of each building in the forest of buildings. At this time, as shown in FIG. 4, the first control unit calculates the overlapping front area of a 6-story building, a 15-story building, and a 13-story building (for example, a front area overlapping three times) 420 And, the front area where the 6-story building and the 13-story building overlap each other (eg, the front area overlapped twice) 430, and the 15-story building and the 13-story building overlap each other The front area (eg, the front area overlapping twice) 440, the front area overlapping the one-story building and the eight-story building (eg, the front area overlapping twice) 450, The front area of the 8-story building and the 10-story building overlap each other (eg, the front area overlapping twice) 460, the front area 470 of the non-overlapping 13-story building, and the non-overlapping front area Calculate the front area 480 of the one-story building, the front area 490 of the 8-story building that does not overlap, and the front area 495 of the 10-story building that does not overlap, respectively, The total front area of the first building forest is calculated by summing up the front areas of the calculated buildings.

In addition, the first control unit calculates a first front area ratio by dividing the calculated total front area of the first building forest by the corresponding first lot area.

As such, the first control unit determines the total front area of the 1st building forest to the 8th building forest, and the first front area for each of the remaining 8 directions excluding directions in which the size of the front area coincides among the preset 16 orientations. The area ratio to the eighth front area ratio are calculated respectively. At this time, for each of the eight directions, a code is set to the north or south wind direction based on north, a b code is set to the north-northwest wind or south-southeast wind direction, a c code is set to the northwest or southeast wind direction, and a west-northwest wind Alternatively, the d code is set for the southeast or east wind direction, the e code is set for the westerly or east wind direction, the f code is set for the southwest or northeast wind direction, the g code is set for the southwest or northeast wind direction, and the south southwest or north wind direction is set. The h code may be set in the northeast wind direction.

In addition, as shown in FIG. 5, the first control unit uses the number of floors (GRO_FLO_CO) of the buildings included in the building layer in the digital map data to create 8 front-area drawings in consideration of the rotation range of the site according to the wind direction. 500 (for example, first to eighth front-side pictures) are respectively generated.

In addition, as shown in FIG. 5, the first control unit displays a projection reference front area (eg, the total front area of the first building forest to the total front of the eighth building forest) on one side of the generated eight front area pictures. area), respectively.

In addition, as shown in FIG. 5, the first control unit changes the file name of the corresponding front-side picture to include the wind direction (or unique code) and site ID for the eight created front-side picture-related files. Set up.

In addition, as shown in FIG. 6 , the first control unit stores a field 621 in a first table 620 set in advance in order to record the front area, front area ratio, and air permeability ranking according to eight wind directions 610 . , 622) is added.

In addition, as shown in FIG. 6, the first control unit determines the total front area of the first to eighth forests of buildings for each of the calculated wind direction codes and the first front area ratio for each of the calculated wind direction codes. th to eighth front area ratios are respectively recorded in the front area field for each wind direction code and the front area ratio field for each wind direction code in the first table.

In addition, as shown in FIG. 6, the first control unit arranges the first to eighth front area ratios in ascending order, and according to the order in which the front area is arranged in ascending order, the b code and g The first building forest ventilation analysis result (or The first table) is created (S330).

Thereafter, the control unit 150 integrates the ventilation analysis result of the building forest (or the ventilation analysis map of the surrounding building forest) with the wind rose diagram and visualizes it.

That is, the controller 150 generates (or writes/designs/composes/manufactures) a layout map for integrating and visualizing the ventilation analysis result of the building forest with the wind rose map. Here, the background map is formed in a square shape, a reference circle display area for displaying the wind rose map accurately in the center, a wind rose map display area for adding a wind rose map to the center, and eight preset wind directions. It includes a ventilation analysis result display area for building forests for displaying the ventilation analysis results (including, for example, ranking of front area ratio, front area ratio, etc.) corresponding to the location of the building forest ventilation analysis result on a plane Cartesian coordinate system.

In addition, the control unit 150 inserts (or adds/applies/reflects/displays) the ventilation analysis result of the building forest in the created (or created/designed/constructed/manufactured) background map.

That is, the control unit 150 adds a front area ratio ranking and a front area ratio for each preset wind direction to the ventilation analysis result display area of the building forest formed along the outer circumferential surface of the generated background map.

In addition, the control unit 150 generates a wind rose diagram based on the wind speed, wind direction frequency, etc. related to the specific weather observation location measured by a weather observation device (not shown) (or received from the weather observation device) ( or written). At this time, the control unit 150 may download (or receive/receive) a wind rose map related to the specific weather observation location from the Korea Meteorological Administration server (not shown) through the communication unit 110 .

In addition, the control unit 150 inserts (or adds/applies/reflects/displays) the generated wind rose map to the background map reflecting the ventilation analysis result of the building forest, and determines the wind frequency and surroundings for a specific meteorological observation location. Create (or create/construct) an integrated wind rose map (or integrated chart) that integrates the results of air permeability analysis of the building forest and the wind rose map, which can view the ventilation environment caused by the building forest.

For example, as shown in FIG. 7 , the first control unit generates a first background map 700 for visualization by integrating the ventilation analysis result of the building forest with a wind rose map.

In addition, as shown in FIG. 7, the first control unit is configured for each of eight wind directions preset in the first building forest ventilation analysis result display area 710 formed on one side of the generated first background map 700. The rank of the front area ratio, the front area ratio, etc. are added (720), respectively.

In addition, as shown in FIG. 8 , the first control unit generates a first wind rose diagram 800 based on wind speed, wind direction frequency, etc. related to the first meteorological observation location.

In addition, as shown in FIG. 9, the first control unit inserts the generated first wind rose diagram 920/800 into the first background map 910 reflecting the ventilation analysis result of the first building forest, 1 An integrated wind rose map 900 is created (S340).

Thereafter, the control unit 150 collectively builds a wind rose map (or the integrated wind rose map/integrated chart) including the ventilation analysis result of the building forest and uses it for model grid-based evaluation.

That is, the control unit 150 analyzes the spatial structure and wind relationship of individual grids of the numerical model composed of matrices in detail to improve the urban canopy model for improving the accuracy of urban weather forecasting. A plurality of integrated wind rose maps are respectively generated (or created) for each of a plurality of meteorological observation positions at which wind rose maps are created.

In addition, the control unit 150 applies the generated plurality of integrated wind rose maps for each of the plurality of weather observation locations (or integrated wind rose map for each of the plurality of grids) to individual grids of the numerical model composed of the matrix and displays them.

In addition, the control unit 150 describes the wind environment of a city or small town by selecting several important points to be used in urban planning such as a district unit plan reflecting the location of each weather observation network to be densely built in each city. Visualize the ventilation environment in the area where

For example, the first control unit obtains second through 156th integrated wind rose diagrams by analyzing the relationship between the spatial structure of a building forest and the wind for each of a plurality of grids (for example, 12×13=156 grids). are additionally generated, and as shown in FIG. 10 , the generated first through 156th integrated wind rose maps are applied to the plurality of grids (1010) and displayed.

In addition, as shown in FIG. 10, among the plurality of lattices, the 111th lattice, the 112th lattice, the 113th lattice, the 123rd lattice, the 124th lattice, the 125th lattice, the 135th lattice, the 136th lattice, and the 137th lattice When a block 1020 including a grid is selected, the first controller displays a screen 1030 corresponding to the selected block 1020 . Here, the screen 1030 corresponding to the selected block 2820 may be in a state including four integrated wind rose maps 1031 corresponding to four wind rose weather observation positions.

Also, as shown in FIG. 11 , the first controller displays a screen 1100 including a plurality of integrated wind rose diagrams for each wind direction with respect to a specific grid among the plurality of grids (S350).

As described above, in the embodiment of the present invention, data related to a building forest around a specific weather observation location at which a wind rose map is created is constructed, and based on the building forest related data related to the constructed specific weather observation location. By analyzing the ventilation characteristics and visualizing the analysis results by integrating them with the wind rose map, the accuracy and probability of visual interpretation are improved. can contribute to a scientific approach.

The foregoing may be modified and modified by those skilled in the art without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention, but to explain, and the scope of the technical idea of the present invention is not limited by these embodiments. The protection scope of the present invention should be construed according to the claims below, and all technical ideas within the equivalent range should be construed as being included in the scope of the present invention.

100: Wind rose map creation device integrated with air permeability analysis for building forests
110: communication unit 120: storage unit
130: display unit 140: audio output unit
150: control unit

Claims (10)

A communication unit that accesses the National Geographic Information Institute server and collects digital map data; and
A pre-processing function is performed on the collected digital map data, and a wind rose map extracted according to the pre-processing function is created for the specific weather observation location based on data related to the surrounding building forest corresponding to the specific weather observation location. A control unit that performs a ventilation analysis function in the building forest and generates an integrated wind rose diagram by integrating the ventilation analysis result of the building forest with the wind rose diagram,
The control unit,
Creating a background map for visualization by integrating the ventilation analysis result of the building forest with a wind rose map, inserting the ventilation analysis result of the building forest into the generated background map, and measuring the specific weather observation location and A wind rose map is generated based on the related wind speed and wind direction frequency, and the generated wind rose map is inserted into the background map reflecting the ventilation analysis result of the building forest, and the wind frequency and the surrounding building forest for a specific weather observation location A wind rose drawing device integrated with a building forest air permeability analysis, characterized in that it generates an integrated wind rose map in which the wind rose map and the result of the air permeability analysis of the building forest can be viewed together. According to claim 1,
The control unit,
Based on the collected digital map data, the data related to the forest of buildings around the preset area, which is the main measurement item related to the analysis of the site to be referred to for quantification of the ventilation of the forest of buildings around the specific weather observation location where the wind rose map is created, An apparatus for creating a wind rose diagram incorporating an analysis of air permeability in a forest of buildings, characterized in that for extracting. According to claim 2,
The data related to the surrounding building forest,
A wind rose map creation device integrated with ventilation analysis of buildings, characterized in that it includes a building area, a building height, and a site area for one or more buildings included in a preset grid centered on the specific weather observation location. Collecting digital map data by accessing the National Geographic Information Institute server by the communication unit;
performing a pre-processing function on the collected digital map data by a control unit;
Performing, by the control unit, a ventilation analysis function for the specific weather observation location based on data related to the surrounding building forest corresponding to the specific weather observation location where the wind rose map extracted according to the performance of the preprocessing function is created ; and
Generating, by the control unit, an integrated wind rose map by integrating the ventilation analysis result of the building forest with the wind rose map,
The step of generating the integrated wind rose map,
generating a background map for visualization by integrating the ventilation analysis result of the building forest with a wind rose map;
inserting a ventilation analysis result of the building forest into the generated background map;
generating a wind rose diagram based on wind speed and wind direction frequency associated with the specific weather observation location measured through a weather observation device; and
By inserting the generated wind rose diagram into the background map reflecting the ventilation analysis result of the building forest, the wind frequency and ventilation environment due to the surrounding building forest can be seen together for a specific weather observation location, and the result of the analysis of the ventilation of the building forest A method of creating a wind rose map integrated with an air permeability analysis of a building forest, comprising a process of generating an integrated wind rose map in which the wind rose map is integrated. According to claim 4,
The step of performing the building forest ventilation analysis function,
setting a unique code for each of a plurality of directions except for directions in which the size of the front area coincides among preset orientations;
For each of the plurality of directions, the front area of individual buildings constituting the building forest facing each other based on the wind direction set from the specific weather observation location is calculated, and the front area of each building constituting the calculated building forest is Calculating the total front area of a plurality of building forests by summing them up;
calculating a plurality of front area ratios by dividing the calculated total front area of the plurality of buildings in each of the plurality of directions by a plurality of site areas according to each wind direction;
arranging ranks in which ventilation is high among the calculated plurality of front area ratios for each of the plurality of directions; and
Creating a table that is a result of ventilation analysis of a building forest by performing a forest ventilation analysis function including a total front area of a plurality of building forests, a plurality of front area ratios, and a ventilation rank calculated for each of the plurality of directions A method of creating a wind rose diagram incorporating the analysis of the air permeability of a building forest. According to claim 5,
The table is
Front area display field for displaying the total front area of the building forest, front area ratio display field for displaying the front area ratio, ventilation ranking display field for displaying the ventilation ranking, grid number display field for displaying the grid number, grid area A lattice area display field for displaying the surface area ratio, a surface area ratio display field for displaying the plane area ratio, an average height display field for displaying the average height, a maximum height display field for displaying the maximum height, and a standard deviation for displaying the standard deviation. A method of creating a wind rose diagram incorporating air permeability analysis of a building forest, characterized in that it consists of a display field. According to claim 5,
The step of performing the building forest ventilation analysis function,
generating a plurality of front-area drawings for each of a plurality of directions in consideration of a rotational range of the site according to a wind direction by using the shape and number of floors of the buildings included in the building layer in the digital map data;
inserting the total front area of the plurality of building forests into the generated plurality of front area pictures; and
A method of creating a wind rose map integrated with air permeability analysis of building forests, further comprising the step of generating names of the plurality of front-side picture-related files including wind direction and unique identification information of the site. delete According to claim 7,
The background map,
It is composed of a square, and a reference circle display area for displaying a wind rose map in the center, a wind rose map display area for adding a wind rose map in the center, and a building corresponding to the positions of a plurality of preset wind directions. A method of creating a wind rose map integrated with forest ventilation analysis, comprising a display area for displaying a forest ventilation analysis result for displaying a forest ventilation analysis result on a plane rectangular coordinate system. According to claim 4,
The control unit further comprises the step of collectively building a wind rose map including the ventilation analysis result of the building forest and utilizing it for model grid-based evaluation.

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