KR102532686B1 - Building Wind Environment Observation System - Google Patents

Abstract

A building wind environment observation system is disclosed. The building wind environment observation system according to an embodiment of the present invention transmits data obtained by applying real-time Meteorological Agency data collected through a meteorological agency protocol analysis to a wind tunnel experimental device that simulates the topography and buildings of an observation target area to a monitoring unit data collection unit; Monitoring that creates a data platform using the building wind environment data received from the data collection unit and the Korea Meteorological Agency data collected through the Korea Meteorological Administration protocol analysis, and analyzes it through building wind simulation for computational fluid analysis using the created data platform. wealth; And risk prediction data according to the results analyzed by the monitoring unit, building wind risk information map is generated using the building wind data chart, the analysis result and the building wind risk information map are stored and visualized, and displayed to the user through a display or application. Building wind hazard information map generation unit; to include the gist of the configuration.
According to the present invention, a multi-purpose building wind environment monitoring system that can effectively cope with emergency situations that may occur in downtown areas such as continuous weather environment information survey and observation, building wind disaster prevention, disaster risk area forecasting, warning, etc. It is possible to provide a building wind environment observation system that can accurately predict building wind environment data through a building model, which is necessary to construct a building wind risk information map through a building model.

Description

Building wind environment observation system {Building Wind Environment Observation System}

The present invention relates to a building wind environment observation system, and more particularly, to a building wind environment observation system including a building model for constructing a building wind risk information map.

Currently, the number of typhoons that invade high-rise Korea has reached an average of 3.9 per year for the past 10 years, and in particular, in 2019, 7 typhoons are found to have had a direct or indirect effect (Korea Meteorological Administration 2019). In particular, due to the influence of climate change, typhoons and local gusts with maximum wind speeds exceeding 40 m/s occur frequently and tend to increase.

Accordingly, in coastal areas, such as Haeundae-gu, Busan, where high-rise buildings are concentrated or the density is increasing, disasters such as falling attachments caused by building winds, spreading flying objects, and generating noise occur, causing a lot of damage to local residents due to strong winds. It is becoming.

Therefore, there is a need for a multi-purpose building wind environment monitoring method that can effectively cope with emergency situations that may occur at sea, such as continuous weather environment information survey and observation, building wind disaster prevention, disaster risk area forecasting and warning, etc. .

In order to solve this problem, a weather monitoring system including the configuration shown in FIG. 1 has been developed.

In the case of a weather monitoring system according to the prior art, a forecast time with the highest forecast accuracy is selected and provided among a plurality of common forecast weather information for each point in time using a medium-scale regional weather model (WRF), especially for the accident point. .

However, the meteorological monitoring system according to the prior art has a problem in that the accuracy of predicted meteorological information is not high because it cannot overcome the limitations of incomplete observation points and missing data.

Therefore, there is a need for a technique capable of solving the above-mentioned problems according to the prior art.

Korean Registered Patent Publication No. 10-1984546 (registration date: May 27, 2019)

The purpose of the present invention is a multi-purpose building wind environment monitoring system that can effectively cope with emergency situations that may occur in downtown areas, such as continuous weather environment information survey and observation, building wind disaster prevention, disaster risk area forecasting, warning, etc. To provide a building wind environment observation system that can accurately predict building wind environment data through a building model, which is necessary to construct a building wind risk information map.

Building wind environment observation system according to one aspect of the present invention for achieving this object is obtained by applying real-time meteorological office data collected through meteorological agency protocol analysis to a wind tunnel experimental device that simulates the topography and buildings of the observation target area a data collection unit that transmits data to the monitoring unit; Monitoring that creates a data platform using the building wind environment data received from the data collection unit and the Korea Meteorological Agency data collected through the Korea Meteorological Administration protocol analysis, and analyzes it through building wind simulation for computational fluid analysis using the created data platform. wealth; And risk prediction data according to the results analyzed by the monitoring unit, building wind risk information map is generated using the building wind data chart, the analysis result and the building wind risk information map are stored and visualized, and displayed to the user through a display or application. It may be configured to include; building wind hazard information map generating unit.

In one embodiment of the present invention, the wind tunnel test apparatus is installed in a detachable structure in a through-hole formed on the installation surface of the terrain to be tested, and a hollow cylindrical installation column extending upward by a predetermined height. wealth; A bottom surface mounted in a form surrounding the outer circumferential surface of the installation column, a side wall surface extending upward by a predetermined height from the floor surface to form a side wall of the building model, and a detachable structure mounted on the upper end of the side wall surface to seal the upper surface. Building model forming unit including a ceiling surface to do; a measuring tube connected to a plurality of measuring holes spaced apart from each other at a predetermined interval on the side wall of the building model forming part and an installation pillar to communicate with each other; A flow rate detector mounted on the outer circumferential surface of each of the measurement tubes in a detachable structure, bound in a form that communicates with the inside of the measurement tube, detects the flow rate of air flowing through the measurement tube, and transmits it to the data collecting unit; a data aggregation unit that is mounted on the installation pillar unit and stores the data collected from each flow rate detection unit in accordance with a real-time timeline; It may be configured to include; and a control unit mounted on the mounting pillar and transmitting the data stored in the data collecting unit to the monitoring unit.

In one embodiment of the present invention, the wind tunnel test building model has a thin plate structure attached to the side wall surface in a regular polygonal structure having a predetermined area, arranged around each measurement hole, and opening the measurement hole to the outside. A first light emitting thin plate having a through hole and emitting a predetermined color in response to a control signal transmitted from a control unit; And a thin plate-like structure attached to the side wall surface in a rectangular structure having a predetermined area, disposed adjacent to the edge of the side wall surface, disposed at a position where the measurement hole is not formed, and a predetermined color by a control signal transmitted from the control unit. It may be configured to include; a second light emitting thin plate that emits light.

In this case, the control unit controls to output a predetermined color corresponding to the flow rate detected from each measuring hole from the first light emitting thin plate attached to the corresponding measuring hole, and the control unit is adjacent to each second light emitting thin plate. The same color as the attached first light emitting thin plate is output, and the control unit controls the color output from each first light emitting thin plate to be output as a gradation color in which adjacent colors can be naturally continued with each other. .

In one embodiment of the present invention, the flow rate detection unit is bound in a form in communication with the outer circumferential surface of each of the measuring tubes, detecting binding unit forming a protruding structure formed by a predetermined height from the inner circumferential surface of the measuring tube; A detection housing formed in an integrated structure with the detection coupling part, protruding and extending from the outer circumferential surface of the measuring tube by a predetermined height to form a storage space of a predetermined volume therein, and having a vent hole communicating with the internal storage space on the upper surface thereof. ; a capillary tube forming portion formed in a form communicating with the inner storage space of the detection housing from the central portion of the protrusion structure of the detection coupling unit; A support structure formed continuously along both sides of the inner storage space of the detection housing and having a structure that supports the lower rim of the hydraulic reaction thin plate by being sealed and bound to the lower rim of the hydraulic reaction thin plate; a thin plate structure mounted on the upper part of the support structure and having a structure changed according to the inflow and outflow of the hydraulic reaction fluid; A deformation amount detection element mounted on the upper surface of the hydraulic reaction thin plate, detecting the amount of deformation of the hydraulic reaction thin plate in real time and transmitting it to the data collecting unit through a wireless communication module; a negative pressure reaction fluid injected into the space formed by the lower surface of the hydraulic reaction thin plate from the capillary tube forming unit and flowing along the capillary tube forming unit by the negative pressure formed at the lower end of the capillary tube forming unit; and a wireless communication module installed in the internal storage space of the detection housing and transmitting the data acquired from the change amount detection element to the data collection unit in real time.

As described above, according to the building wind environment observation system of the present invention, a wind tunnel test apparatus having a specific structure, a data collection unit, a monitoring unit, and a building wind risk information map generation unit are provided to continuously investigate and observe meteorological environment information. In addition, it is necessary to build a building wind risk information map through a multi-purpose building wind environment monitoring system that can effectively respond to emergency situations that may occur in downtown areas such as building wind disaster prevention, disaster risk area forecasting, warnings, etc. It is possible to provide a building wind environment observation system that can accurately predict wind environment data through a building model.

1 is a configuration diagram showing a weather monitoring system according to the prior art.
2 is a block diagram showing a building wind environment observation system according to an embodiment of the present invention.
3 is a perspective view showing a building model forming part of a wind tunnel test apparatus according to an embodiment of the present invention.
4 is a longitudinal sectional view showing a state in which a building model of a wind tunnel test apparatus according to an embodiment of the present invention is installed on an installation surface.
5 is an enlarged view of part A of FIG. 4 .
FIG. 6 is a schematic longitudinal cross-sectional view showing how air is introduced through a measuring hole formed on a side wall of the building model shown in FIG. 4 and enters the hollow structure of an installation column through a measuring tube.
7 is a longitudinal cross-sectional view showing a state in which a building model forming part having various heights and widths is replaced and installed on an installation pillar according to an embodiment of the present invention.
8 is a longitudinal cross-sectional view showing a state in which the height of a building model is changed and installed by further stacking another installation pillar part and a side wall extension part on an installation pillar part according to an embodiment of the present invention.
9 is a front view showing only the measuring tube mounted inside the building model forming unit of the present invention.
10 is a longitudinal cross-sectional view showing a flow rate detector mounted on the measuring tube shown in FIG. 9;
11 is a longitudinal cross-sectional view showing only the flow rate detector shown in FIG. 10;
12 is a longitudinal cross-sectional perspective view showing a flow rate detector according to an embodiment of the present invention.
FIG. 13 is a plan view illustrating a hydraulic reaction thin plate, a deformation amount detection element, and a support structure of the flow rate detection unit shown in FIG. 12 .
FIG. 14 is a longitudinal cross-sectional view showing a state in which the hydraulic reaction thin plate is deformed as air flows through the measuring tube shown in FIG.
15 is a perspective view showing a first light emitting thin plate and a second light emitting thin plate mounted on a side wall surface according to another embodiment of the present invention.
16 is a control configuration diagram showing the flow of controlling the operation of the first light-emitting thin plate and the second light-emitting thin plate of the wind tunnel test apparatus according to another embodiment of the present invention.
17 is a front view showing a building model forming part of the wind tunnel test apparatus according to this embodiment of the present invention.
18 is a front view showing a state in which the first light emitting thin plate and the second light emitting thin plate are mounted on the side wall surface of the building model forming part shown in FIG. 17;
19 is a front view showing an operating state of the first light emitting thin plate and the second light emitting thin plate shown in FIG. 18;
FIG. 20 is a front view showing a state in which the first light emitting thin plate and the second light emitting thin plate shown in FIG. 18 are output in gradation colors.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the drawings. Prior to this, terms or words used in this specification and claims should not be construed as limited to ordinary or dictionary meanings, but should be interpreted as meanings and concepts consistent with the technical spirit of the present invention.

Throughout this specification, when a member is said to be located “on” another member, this includes not only a case where a member is in contact with another member, but also a case where another member exists between the two members. Throughout this specification, when a certain component is said to "include", it means that it may further include other components without excluding other components unless otherwise stated.

2 is a block diagram showing a building wind environment observation system according to an embodiment of the present invention.

Referring to FIG. 2, the building wind environment observation system according to the present embodiment includes a wind tunnel test apparatus 100, a data collection unit 101, a monitoring unit 102, and building wind risk information map that perform specific roles. By having the unit 103, it is possible to effectively cope with emergency situations that may occur in downtown areas, such as building wind disaster prevention, disaster risk area forecasting, warning, as well as continuous weather environment information investigation and observation. It is possible to provide a building wind environment observation system that can accurately predict building wind environment data through a building model, which is necessary to build a building wind risk information map through a monitoring system.

Specifically, the data collection unit 101 of the building wind environment observation system according to the present embodiment is real-time meteorological agency data collected through the meteorological agency protocol analysis in the wind tunnel experimental device 100 that simulates the topography and buildings of the observation target area. Data obtained by applying may be transmitted to the monitoring unit.

The monitoring unit 102 of the building wind environment observation system according to the present embodiment generates a data platform 102a using the building wind environment data received from the data collection unit and the Korea Meteorological Agency data collected through the protocol analysis of the Korea Meteorological Administration. And, it can be analyzed through the building wind simulation 102b for computational fluid analysis using the generated data platform.

Specifically, the monitoring unit 102, upon request for data storage collected by the data collection unit, data including a data distribution storage model for storing in distributed data nodes and a data retrieval model for multi-user request processing and data retrieval. Using the data platform, building wind environment data and Meteorological Administration data are processed and provided in the form of data required for building wind simulation, and building wind simulation is performed by setting the data input and output boundaries (In/Out Bound).

In addition, the monitoring unit 102 performs a building wind simulation for computational fluid analysis by generating a building wind risk target area in three dimensions and setting a flow field through which the fluid flows. Then, based on the building wind simulation results, the effect of the building wind is predicted, the wind speed and wind speed increase rate are analyzed to derive the area affected by the building wind and the risk area, and the wind path of the building wind is analyzed to predict the change in the wind environment of the building wind for each wind direction and the maximum Calculate the wind speed and analyze the expected risk area of building wind.

Meanwhile, the building wind risk information map generation unit 103 of the building wind environment observation system according to the present embodiment maps the building wind risk information using the risk prediction data and the building wind data chart according to the results analyzed by the monitoring unit. , store and visualize analysis results and building wind risk information maps, and provide them to users through displays or applications.

Specifically, the building wind risk information map generation unit 103 generates a building wind risk information map using the risk prediction data and the building wind data chart according to the results analyzed by the monitoring unit 102, and the analysis result and the building wind hazard information map are generated. Saves and visualizes the wind risk information map and presents it to the user through a display or application

In addition, the building wind risk information map generation unit 103 provides risk information through computational fluid analysis, and visualizes information related to the danger area and building wind risk in conjunction with the disaster safety application in the dangerous area and the website of each region. Create and provide a building wind hazard information map. Safety information is provided by providing risk information for each situation, manuals in case of emergency, education and promotional materials related to building winds, and real-time monitoring data.

Hereinafter, the wind tunnel test apparatus 100 according to the present embodiment will be described in more detail.

3 is a perspective view showing the building model formation part of the wind tunnel test building model according to an embodiment of the present invention, and FIG. 4 shows the building model of the wind tunnel test building model according to an embodiment of the present invention on the installation surface. A longitudinal cross-sectional view showing an installed state is shown, and FIG. 5 is an enlarged view of part A of FIG. 4 . In addition, FIG. 6 is a schematic longitudinal cross-sectional view showing how air is introduced through a measuring hole formed on the side wall of the building model shown in FIG. 4 and enters the hollow structure of the installation column through the measuring tube, and FIG. 7 In is a longitudinal cross-sectional view showing a state in which building model forming parts having various heights and widths are installed in exchange for installation pillars according to an embodiment of the present invention. In addition, Figure 8 is a longitudinal cross-sectional view showing a state in which the height of the building model is changed and installed by further stacking another installation pillar and a side wall extension on the installation pillar according to an embodiment of the present invention.

Referring to these drawings, the wind tunnel test building model 100 according to the present embodiment includes an installation pillar 110 of a specific structure, a building model forming unit 120, a measuring tube 130, and a first pillar binding structure ( 111) and the second pillar binding structure 112, it is possible to solve the problem of separately manufacturing or reconstructing a building model of various structures mounted on the terrain to be tested each time or by combining multiple models, and building model production It is possible to solve the problem of taking a long time in installing a connector connected to one or more measuring holes (122a) through which wind enters the front and side of the city, and to install a building model stably on top of the terrain structure, a separate We can provide a wind tunnel test building model that includes configurations that can solve additional processes and lengthy problems.

Hereinafter, each component constituting the wind tunnel test building model 100 according to the present embodiment will be described in detail with reference to drawings.

The installation column 110 of the wind tunnel test building model 100 according to this embodiment is detachably installed in a through hole formed on the installation surface 10 of the terrain to be tested, and is installed in a predetermined upward direction. It is a hollow cylindrical structure that extends as high as it is.

Specifically, the installation pillar 110 may have a structure including a pillar through hole 113, a recessed groove 114, and a first magnetic member 115 of a specific structure. A plurality of pillar through-holes 113 of the installation pillar 110 are formed at regular intervals on the outer circumferential surface of the installation pillar 110, and are in communication with the central hollow structure, and one end of the measuring tube 130 It is a structure that is connected by a structure that communicates with. The recessed groove 114 of the installation pillar 110 is adjacent to the pillar through-hole 113 and is formed in a structure recessed by a predetermined depth from the outer circumferential surface of the installation pillar 110. The first magnetic member 115 of the installation pillar 110 is mounted in the recessed groove 114, and is attached to the second magnetic member 131 mounted on one end of the measuring tube 130 by magnetism. It is a structure that becomes At this time, as shown in FIG. 5, it is preferable that the first magnetic member 115 and the second magnetic member 131 having a ring structure attached by magnetism are mounted on one end of the measurement tube 130.

The building model forming part 120 according to the present embodiment extends upward by a predetermined height from the bottom surface 121 mounted in a form surrounding the outer circumferential surface of the installation pillar part 110 and the bottom surface 121 to form a building model. It is configured to include a side wall surface 122 forming a side wall, and a ceiling surface 123 mounted in a detachable structure at an upper end of the side wall surface 122 to seal the upper surface.

Specifically, the building model forming unit 120 may have a structure including a bottom surface 121, a side wall surface 122, and a ceiling surface 123 of a specific structure. The bottom surface 121 of the building model forming part 120 is a plate-shaped structure that is mounted in a surface contact with the installation surface, and the installation pillar part 110 has an assembly through hole 126 having the same inner diameter as the outer peripheral surface at the center This structure is formed The side wall surface 122 of the building model forming unit 120 is an integral structure along the edge of the bottom surface 121 and extends upward by a predetermined height to form the side wall of the building model, and has a downward binding structure along the upper edge ( 125) and a structure in which an upward binding structure 124 of a structure bound in a detachable structure is formed. The ceiling surface 123 of the building model forming part 120 is engaged with the upper binding structure 124 formed on the upper end of the side wall surface 122 and the lower binding structure 125 of a structure that is detachable and bound is the lower surface edge. It is formed continuously along and has a structure that seals the upper open surface of the side wall surface 122.

The first pillar binding structure 111 according to the present embodiment is formed at the upper end of the installation pillar part 110 and is detachable by being engaged with the second pillar binding structure 112 of another installation pillar part 110. It is a structure that binds In addition, the second pillar binding structure 112 is formed at the lower end of the installation pillar part 110, and is engaged with the first pillar binding structure 111 of another installation pillar part 110 to be bound in a detachable structure. am.

At this time, as shown in FIGS. 7 and 8, according to the intention of the operator or designer, the building model forming part 120 having various heights and widths can be replaced and installed on the installation pillar 110, and the installation pillar ( 110), the height of the building model can be changed and installed by further stacking another installation pillar 110 and the side wall extension 127.

Specifically, the side wall extension part 127 according to the present embodiment is configured to form a side wall structure continuous with the side wall surface 122, and extends by a predetermined height to form the side wall of the building model, and is bound upward along the upper edge. A structure 124 is formed, and a lower binding structure 125 is formed along the lower edge.

9 is a front view showing only the measuring tube mounted inside the building model forming unit of the present invention, and FIG. 10 is a longitudinal cross-sectional view showing the flow rate detector mounted on the measuring tube shown in FIG. 9, FIG. 11 is a longitudinal cross-sectional view showing only the flow rate detector shown in FIG. 10 . In addition, FIG. 12 is a longitudinal cross-sectional perspective view showing the flow rate detection unit according to an embodiment of the present invention, and FIG. 13 is a plan view showing the hydraulic reaction thin plate, the deformation amount detection element, and the support structure of the flow rate detection unit shown in FIG. 12. has been In addition, FIG. 14 is a longitudinal cross-sectional view showing a state in which the hydraulic reaction thin plate is deformed as air flows through the measuring tube shown in FIG. 10 and the position of the negative pressure reaction fluid is changed along the capillary formed in the projection structure of the flow rate detector there is. 15 is a perspective view showing a first light emitting thin plate and a second light emitting thin plate mounted on the side wall surface according to another embodiment of the present invention, and FIG. 16 is a wind tunnel test building model according to another embodiment of the present invention. A control configuration diagram showing the flow of controlling the operation of the first light emitting thin plate and the second light emitting thin plate is shown.

Referring to these drawings, the measuring tube 130 according to the present embodiment includes a plurality of measuring holes 122a formed at regular intervals on the side wall surface 122 of the building model forming part 120 and the installation pillar part 110 It is a structure that connects to communicate.

At this time, the flow rate detection unit 140 is mounted on the outer circumferential surface of each measuring tube 130 in a detachable structure.

Specifically, the flow rate detection unit 140 is configured to be coupled in communication with the inside of the measurement tube 130, detects the flow rate of air flowing through the measurement tube 130, and then transmits it to the data collection unit 150. can

The above-mentioned data collection unit 150 is a component mounted on the installation pillar unit 110, and can store the data obtained from each flow rate detection unit 140, collect them along a real-time timeline, and store them therein.

At this time, the control unit 160 mounted on the installation pillar 110 may transfer the data stored in the data collection unit 150 to the PC of the experiment operator.

10 to 14, the flow rate detection unit 140 according to the present embodiment includes a detection coupling unit 141, a detection housing 143, a capillary tube forming unit 145, and a support structure 146 having a specific structure. , It may be configured to include a hydraulic reaction thin plate 147, a deformation amount detection element 148, a negative pressure reaction fluid (145a) and a wireless communication module (149).

Specifically, the detection coupling unit 141 of the flow rate detection unit 140 is configured to be bound in a form that communicates with the outer circumferential surface of each measuring tube 130, and is a protrusion protruding from the inner circumferential surface of the measuring tube 130 by a predetermined height. Structure 142 may be formed. The detection housing 143 of the flow rate detection unit 140 is formed as an integral structure with the detection coupling unit 141, and protrudes and extends from the outer circumferential surface of the measuring tube 130 by a predetermined height to form a storage space of a predetermined volume therein, , It is a structure in which a vent hole 144 communicating with the internal storage space is formed on the upper surface. The capillary tube forming unit 145 of the flow rate detection unit 140 is a structure formed in a form communicating with the inner storage space of the detection housing 143 from the center of the projection structure 142 of the detection coupling unit 141 . The support structure 146 of the flow rate detection unit 140 is continuously formed along both sides of the inner storage space of the detection housing 143, and sealed with the lower edge of the hydraulic reaction thin plate 147 to seal the hydraulic reaction thin plate 147 ) It is a structure that supports the lower surface rim of the The hydraulic reaction thin plate 147 of the flow rate detection unit 140 has a thin plate structure mounted on the upper portion of the support structure 146, and is a structure that is changed according to the inflow and outflow of the hydraulic reaction fluid. The deformation amount detection element 148 of the flow rate detection unit 140 is configured to be mounted on the upper surface of the hydraulic reaction thin plate 147, and detects the deformation amount of the hydraulic reaction thin plate 147 in real time and transmits data through the wireless communication module 149. It can be delivered to the gathering unit 150. The negative pressure reaction fluid 145a of the flow rate detection unit 140 is injected into the space formed by the lower surface of the hydraulic reaction thin plate 147 from the capillary tube forming unit 145, and is formed at the bottom of the capillary tube forming unit 145 It can flow along the capillary tube forming part 145 by negative pressure. In addition, the wireless communication module 149 of the flow rate detection unit 140 is mounted in the internal storage space of the detection housing 143, and can transmit data acquired from the change amount detection device to the data collection unit 150 in real time. .

17 is a front view showing the building model forming part of the wind tunnel test building model according to this embodiment of the present invention, and in FIG. 18, the first light emitting thin plate and the second light emitting thin plate are on the side wall surface of the building model forming part shown in FIG. 17 A front view showing a state in which the thin plate is mounted is shown. In addition, FIG. 19 is a front view showing the operating state of the first light emitting thin plate and the second light emitting thin plate shown in FIG. 18, and FIG. 20 shows the first light emitting thin plate and the second light emitting thin plate shown in FIG. 18 in gradation colors. A front view showing a controlled state to be output as is shown.

Referring to these drawings together with FIGS. 15 and 16, a first light emitting thin plate 171 and a second light emitting thin plate 172 performing a specific role may be further mounted on the side wall surface 122 according to the present embodiment. .

Specifically, the first light emitting thin plate 171 according to the present embodiment is a thin plate structure attached to the side wall surface 122 in a regular polygonal structure having a predetermined area, and is disposed around each measurement hole 122a, and measures A through hole is formed to open the ball 122a to the outside, and a predetermined color may be emitted by a control signal transmitted from the controller 160 .

In addition, the second light emitting thin plate 172 according to the present embodiment is a thin plate structure attached to the side wall surface 122 in a rectangular structure having a predetermined area, and is disposed adjacent to the edge of the side wall surface 122, and has a measuring hole. 122a is not formed, and a predetermined color can be emitted by a control signal transmitted from the control unit 160 .

At this time, the control unit 160 can control to output a preset color corresponding to the flow rate detected from each measurement hole 122a from the first light emitting thin plate 171 attached to the corresponding measurement hole 122a. In addition, the control unit 160 can control each second light emitting thin plate 172 and the same color as the first light emitting thin plate 171 attached adjacently to be output. At this time, as shown in FIG. 20 , the control unit 160 may control colors output from each of the first light emitting thin plates 171 to be output as gradation colors in which adjacent colors can be naturally continuous with each other.

As described above, according to the building wind environment observation system of the present invention, the wind tunnel test apparatus 100 of a specific structure, the data collection unit 101, the monitoring unit 102, and the building wind risk information map generating unit 103 ), a multi-purpose building wind environment monitoring system that can effectively respond to emergency situations that may occur in downtown areas, such as continuous weather environment information survey and observation, building wind disaster prevention, disaster risk area forecasting, warning, etc. It is possible to provide a building wind environment observation system that can accurately predict building wind environment data through a building model, which is necessary to construct a building wind risk information map through a building model.

In the above detailed description of the present invention, only specific embodiments thereof have been described. However, it should be understood that the present invention is not limited to the particular forms mentioned in the detailed description, but rather it is understood to include all modifications, equivalents and substitutes within the spirit and scope of the present invention as defined by the appended claims. It should be.

That is, the present invention is not limited to the specific embodiments and descriptions described above, and anyone having ordinary knowledge in the technical field to which the present invention belongs can make various modifications without departing from the gist of the present invention claimed in the claims. is possible, and such variations fall within the protection scope of the present invention.

101: data collection unit
102: monitoring unit
102a: data platform
102b: data simulation
103: building-like risk information map generating unit
100: wind tunnel test device
110: installation pillar
111: first column binding structure
112: second column binding structure
113: pillar through hole
114: indented groove
115: first magnetic member
120: building model forming unit
121: bottom surface
122: side wall
122a: measuring ball
123: ceiling surface
124: upward binding structure
125: downward binding structure
126: assembly through hole
127: side wall extension
130: measuring tube
131: second magnetic member
140: flow rate detection unit
141: detection binding unit
142: projection structure
143: detection housing
144: vent hole
145: capillary tube forming unit
145a: hydraulic reaction fluid
146: support structure
147: hydraulic reaction sheet
148: deformation amount detection element
149: wireless communication module
150: data gathering unit
160: control unit
171: first light emitting thin plate
172: second light emitting thin plate

Claims (5)

A data collection unit 101 that transmits data obtained by applying real-time Meteorological Agency data collected through a meteorological agency protocol analysis to a wind tunnel experimental device 100 that simulates the topography and buildings of an observation target area to a monitoring unit;
A data platform 102a is created using the building wind wind environment data received from the data collection unit and the Meteorological Agency data collected through the Meteorological Agency protocol analysis, and a building wind simulation 102b is used for computational fluid analysis using the generated data platform. ) Monitoring unit 102 to analyze through; and
A building wind risk information map is created using the risk prediction data and building wind data chart according to the results analyzed by the monitoring unit, and the analysis result and the building wind risk information map are stored and visualized to the user through a display or application. Wind risk information map generator 103;
including,
The wind tunnel test apparatus 100,
An installation pillar 110 having a hollow cylindrical structure that is detachably installed in a through hole formed on the installation surface 10 of the terrain to be tested and extended upward by a predetermined height;
A bottom surface 121 mounted in a form surrounding the outer circumferential surface of the installation pillar part 110, a side wall surface 122 extending upward from the floor surface 121 by a predetermined height to form a side wall of the building model, and a side wall surface A building model forming unit 120 including a ceiling surface 123 attached to the top of 122 in a detachable structure to seal the upper surface;
a measuring tube 130 that connects a plurality of measuring holes 122a spaced apart from each other on the side wall 122 of the building model forming part 120 and the installation pillar 110 so as to communicate with each other;
It is attached to the outer circumferential surface of each of the measurement tubes 130 in a detachable structure, bound in a form that communicates with the inside of the measurement tube 130, and detects the flow rate of air flowing through the measurement tube 130, and then data Flow rate detection unit 140 for transmitting to the collecting unit 150;
A data aggregation unit 150 mounted on the installation pillar 110, integrating data obtained from each flow rate detection unit 140, collecting data according to a real-time timeline, and storing the data therein; and
a controller 160 mounted on the installation pillar 110 and transmitting the data stored in the data collection unit 150 to the monitoring unit 102;
Building wind wind environment observation system comprising a.
delete According to claim 1,
The wind tunnel test building model,
It is a thin plate structure attached to the side wall surface 122 in a regular polygonal structure having a predetermined area, and is disposed around each measuring hole 122a, and a through hole is formed to open the measuring hole 122a to the outside, and a control unit ( 160) a first light emitting thin plate 171 that emits a predetermined color by the control signal transmitted from; and
It is a thin plate structure attached to the side wall surface 122 in a rectangular structure having a predetermined area, is disposed adjacent to the edge of the side wall surface 122, and is disposed at a position where the measuring hole 122a is not formed, and the control unit 160 ) A second light emitting thin plate 172 emitting light of a predetermined color by a control signal transmitted from;
Building wind wind environment observation system comprising a.
According to claim 3,
The controller 160 controls to output a predetermined color corresponding to the flow rate detected from each measuring hole 122a from the first light emitting thin plate 171 attached to the corresponding measuring hole 122a,
The control unit 160 controls so that the same color as the first light emitting thin plate 171 attached adjacent to each second light emitting thin plate 172 is output,
The controller 160 controls the color output from each of the first light emitting thin plates 171 to be output as a gradation color in which adjacent colors can be naturally continuous with each other.
According to claim 1,
The flow rate detection unit 140,
A detection binding unit 141 coupled to the outer circumferential surface of each of the measurement tubes 130 to form a protruding structure 142 protruding from the inner circumferential surface of the measurement tube 130 by a predetermined height;
It is formed in an integrated structure with the detection coupling part 141, protrudes and extends from the outer circumferential surface of the measuring tube 130 by a predetermined height to form a storage space of a predetermined volume inside, and a vent hole communicating with the internal storage space on the upper surface. a detection housing 143 having a structure in which 144 is formed;
a capillary tube forming part 145 formed in a form communicating with the inner storage space of the detection housing 143 from the center of the protrusion structure 142 of the detection coupling part 141;
A support structure formed continuously along both sides of the inner storage space of the detection housing 143 and sealed with the lower edge of the hydraulic reaction thin plate 147 to support the lower edge of the hydraulic reaction thin plate 147 (146);
a thin plate structure mounted on the support structure 146, and a hydraulic reaction thin plate 147 having a structure that changes according to the inflow and outflow of hydraulic reaction fluid;
A deformation amount detection element 148 mounted on the upper surface of the hydraulic reaction thin plate 147, detecting the amount of deformation of the hydraulic reaction thin plate 147 in real time and transmitting it to the data collection unit 150 through the wireless communication module 149;
It is injected into the space formed by the lower surface of the hydraulic reaction thin plate 147 from the capillary tube forming unit 145 and flows along the capillary tube forming unit 145 by the negative pressure formed at the lower end of the capillary tube forming unit 145 negative pressure reaction fluid (145a); and
a wireless communication module 149 mounted in the internal storage space of the detection housing 143 and transmitting the data obtained from the change amount detection element to the data collection unit 150 in real time;
A wind tunnel test building model comprising a.

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