JP5974533B2 - Environmental simulation method for construction site - Google Patents

Description

  The present invention relates to a construction site environment simulation system and a construction site environment simulation method for confirming the influence of the weather environment of a construction site where a building is constructed.

  For buildings, it is obliged to consider the meteorological environment in the state after completion from the design stage, for example, the wind environment, but such consideration is not obliged during construction. For this reason, it has been designed in consideration of the wind environment etc. on the premise of the completed building.

  However, regarding the wind environment, it is desired to consider the influence of the weather environment not only after the completion of construction but also during the construction of the building, in consideration of the residents near the construction site. On the other hand, since the state of the building under construction changes with the progress of the construction, the influence of the wind environment and the like also changes with the progress of the construction. For this reason, there is a problem that it is difficult to confirm in advance the influence of the wind environment during construction.

  The present invention has been made in view of such problems, and the object of the present invention is an environment simulation system for a construction site capable of confirming in advance the influence of the weather environment on the construction site under construction, and It is to provide an environmental simulation method for a construction site.

In addition, a modeling process for generating three-dimensional model data in which a surrounding block of a plurality of buildings to be constructed and a state in each stage of the construction process of the plurality of buildings are modeled based on three-dimensional data,
Weather information associating step for associating based on the weather information data corresponding to the construction period of the plurality of buildings in the surrounding city block to said three-dimensional model data including the construction site of the plurality of building the in construction time of each stage,
On the basis of the said associated with the three-dimensional model data weather information data, simulation step for simulating the influence of weather for the plurality of buildings and the surrounding city block in each stage and,
A construction order determination step for determining a construction order of the plurality of buildings based on the simulation result,
It is the environmental simulation method of the construction site characterized by having.
In addition, a modeling process for generating 3D model data obtained by modeling the surrounding block of the site constructed inside the enclosure wall and the state at each stage of the construction process of the site based on the 3D data,
A meteorological information associating step for associating the three-dimensional model data with the meteorological information data corresponding to the construction period of the site in the surrounding block including the site , based on the construction time of each stage ;
On the basis of the said associated with the three-dimensional model data weather information data, simulation step for simulating the influence of weather for the site and the surrounding city block in each stage and,
Based on the result of the simulation, a dust-proof measure step for inclining the upper part of the enclosure wall toward the site,
It is the environmental simulation method of the construction site characterized by having.
In addition, a modeling process for generating 3D model data obtained by modeling the surrounding block of the site constructed inside the enclosure wall and the state at each stage of the construction process of the site based on the 3D data,
A meteorological information associating step for associating the three-dimensional model data with the meteorological information data corresponding to the construction period of the site in the surrounding block including the site , based on the construction time of each stage ;
On the basis of the said associated with the three-dimensional model data weather information data, simulation step for simulating the influence of weather for the site and the surrounding city block in each stage and,
Based on the simulation result, a dust-proof measure step for planning the entrance and exit of the enclosure into the site,
It is the environmental simulation method of the construction site characterized by having.
In addition, a modeling process for generating three-dimensional model data obtained by modeling the surrounding block of the building to be constructed and the state in each stage of the building construction process based on the three-dimensional data,
A weather information associating step for associating the three-dimensional model data and the weather information data corresponding to the construction period of the building in the surrounding block including the construction site of the building based on the construction time of each stage; and
Based on the weather information data associated with the three-dimensional model data, a simulation step of simulating the influence of weather on the building and the surrounding block in each stage,
Have
Based on the simulation result, the three-dimensional model data is changed to new three-dimensional model data,
Corresponding the new three-dimensional model data and the weather information data based on the construction time of each stage, to simulate the influence of the weather on the building and the surrounding block in each stage,
The generation of the new 3D model data and the simulation for the new 3D model data are repeated until reaching a preset target value,
A construction site environmental simulation method characterized by selecting a construction plan in consideration of the weather information .
Also, an environmental simulation method for such a construction site,
It is desirable that the construction plan is examination of a place suitable for wind power generation during construction, examination of a strong wind notification system, or examination of a communication tool using wind.
According to such an environmental simulation method for a construction site, in each stage of the three-dimensional model data in which the state of the building included in the surrounding block and changed in stages is modeled in three dimensions, Since the weather information data is correlated based on the simulation and the effect of the weather on the building and surrounding block is simulated, the influence of the weather at each stage of the building and surrounding block represented by the 3D model data can be easily confirmed in advance Is possible.

  ADVANTAGE OF THE INVENTION According to this invention, it is possible to provide the environmental simulation system of the construction site which can confirm the influence of the weather environment in the construction site under construction beforehand, and the environmental simulation method of a construction site.

It is a flowchart which shows the process from the design of a building including the environmental simulation method of the construction site implemented using the environmental simulation system of the construction site of this embodiment to completion. It is a flowchart which shows the process from the target setting including the environmental simulation method of a construction site to construction. It is a figure which shows the concept of the three-dimensional model data based on an original construction plan. It is a flowchart which shows the process from simulation to selection of the optimal construction plan. It is a figure for demonstrating an example of the result of having simulated the wind environment in "Zephyrus" (trademark), and Fig.5 (a) is a figure which shows the wind environment in the state which does not take a windbreak countermeasure, FIG. 5B is a diagram showing a wind environment in a state where windproof measures are taken. It is a figure which shows an example of the result of having simulated based on the three-dimensional model data based on an initial construction plan, and the weather information data regarding a wind. FIG. 7A is a diagram showing a normal enclosure wall, and FIG. 7B is a diagram showing an example in which the enclosure wall is extended upward as an example of wind protection measures. FIG.7 (c) is a figure which shows the surrounding wall which inclined the upper part to the construction site side. Fig. 8 (a) shows an example of installing a rubber skirt at the foot of an open / close gate, and Fig. 8 (b) is behind a building where a temporary enclosure gate is constructed. FIG. 8C shows an example in which temporary enclosure gates are provided in two directions, and FIG. 8D shows an example in which a dust collecting device is provided at a position that becomes a strong wind region. FIG. It is a figure which shows an example of the dust-proof measures at the time of dismantling, FIG. 9 (a) is a figure which shows the normal enclosure wall at the time of dismantling construction, FIG.9 (b) is a strong wind with a possibility that work may be interrupted FIG. 9C is a diagram showing an enclosure wall whose upper portion is inclined toward the dismantling site. It is a figure which shows the difference in the wind environment by construction order, FIG. 10 (a) is a figure which shows the wind environment at the time of completion, FIG.10 (b) shows the wind environment at the time of constructing A ridge first. FIG.10 (c) is a figure which shows the wind environment at the time of constructing B building previously. FIG. 11A is a diagram showing the wind environment before rebuilding, and FIG. 11B is a diagram showing the wind environment after rebuilding. (C) is a figure which shows the wind environment during rebuilding construction. It is a figure which shows the concept of the three-dimensional model data based on a new construction plan. It is a figure which shows an example of the result of having simulated based on new three-dimensional model data and the weather information data regarding a wind.

  Hereinafter, an embodiment of an environment simulation system for a construction site and an environment simulation method for a construction site according to the present invention will be described with reference to the drawings.

  FIG. 1 is a flowchart showing a process from building design to completion including a construction site environmental simulation method implemented using the construction site environmental simulation system of the present embodiment.

  In the present embodiment, in the building to be constructed and the surrounding city block of the building, when examining the countermeasures while determining the influence of the wind environment based on the information on the wind as weather information data, when determining the construction plan A construction site environment simulation system and a construction site environment simulation method for confirming in advance the influence of the wind environment at the construction site under construction will be described. In other words, since the state of the building under construction changes with the progress of the construction, not only the completed building but also the entire construction process is divided in stages according to the state of the building, and the influence of the wind environment is confirmed at each stage Then, a construction plan is developed in consideration of the wind environment so as to achieve a preset target value.

  This construction site environmental simulation system stores, for example, so-called three-dimensional CAD data that can generate a three-dimensional model based on the three-dimensional data of the surrounding block of the site where the building is constructed and the designed building. A three-dimensional model generated on the basis of the three-dimensional CAD data in the CAD data storage area and the weather information data in the weather information storage area. Based on the above, it is realized by a computer system equipped with simulation software capable of executing a predetermined arithmetic processing and simulating the influence of the meteorological environment on the building and the surrounding block. An example of such software includes a wind environment simulator “Zephyrus” (registered trademark). In addition, in this computer system, a model of the state of the building at a predetermined timing of the process in which the building is constructed according to the construction plan can be generated as a three-dimensional model generated from the three-dimensional CAD data. For example, BIM (Building Information Modeling) is installed. The three-dimensional model generated by the BIM can appropriately change the modeling timing (stage) in the construction plan and the construction process, and can model the state of the building according to each stage. The system shown here is only an example, and the configuration of the storage area and the software used are not limited to this. The state of the building at each stage of the building construction process is modeled with the surrounding block as a three-dimensional model. Any system capable of simulating the influence of the weather environment based on the three-dimensional model (three-dimensional model data) and the weather information data may be used.

  When constructing a building, as shown in FIG. 1, first, after the building to be designed is completed, it is determined whether or not the completed building needs to be evaluated for wind influence by laws and regulations (S100). When necessary, a design taking into consideration the wind environment is performed (S200). At this time, even if it is not necessary to evaluate the influence of laws and regulations, for example, within the scope of application of the following technology, the design considering the wind environment is performed (S300). The scope of technology is, for example, (1) High-rise buildings or large-scale facilities with a height of approximately 50m or more, etc. that are expected to have a significant impact on the wind environment due to construction (2) The height of the planned building is about 30-50m There are high-rise buildings and large-scale facilities with a height of approximately 50m or more in the surrounding area, and there are concerns about the impact on the wind environment due to multiple factors. (3) Close to railways, expressways, etc. (4) There are residential areas, hospitals, schools, etc. in the surrounding area, and consideration for the influence on the wind environment is required.

  Then, if it is not necessary to design in consideration of the wind environment even in the light of the applicable range of laws and technology, construction is started (S500).

  On the other hand, when it is necessary to design in consideration of the wind environment in light of the applicable scope of laws and technology, construction is performed by the environmental simulation method at the construction site implemented using the environmental simulation system at the construction site of the present invention. A plan is formulated, and construction is started based on the established construction plan (S300).

  FIG. 2 is a flowchart showing a process from target setting to construction including an environmental simulation method at a construction site.

  In the construction site environment simulation method, as shown in FIG. 2, first, a target value for the wind environment is set based on laws and technical scope (target setting step S310). At this time, the target value of the wind environment to be set varies depending on the use purpose of the construction planned site and the surrounding situation. For example, (a) Beaufort wind class, (b) Wind environment evaluation scale proposed by Shuzo Murakami, It is desirable to set based on (c) a wind environment evaluation index proposed by the Institute of Wind Engineering, (d) standards established by the government to which the construction site belongs. In the present embodiment, an example will be described in which a location where a strong wind area requiring wind protection measures affects the outside of the site of the construction site is set to 12 or less in the entire construction process.

  Next, the building is designed, a construction plan for the designed building is formulated, and three-dimensional model data modeled based on the design data is generated (modeling step S320). The 3D model data generated at this time is generated so that the state of the building at each stage of the building construction process can be expressed for each stage based on the established construction plan together with the model of the surrounding block of the building. .

  FIG. 3 is a diagram showing the concept of the three-dimensional model data based on the initial construction plan. In FIG. 3, in order to make the function and effect easier to understand, a front view and a plan view are shown, but the state of the construction site and the surrounding city block is represented by a 3D image.

  As shown in FIG. 3, in the building construction plan of this embodiment, for example, there is a four-story C building between a 22-story A building and a B building that are built side by side in the east-west direction as a building. The project is planned to be completed in two years from the start of construction. The three-dimensional model data of this building assumes that changes in the wind environment, that is, changes in wind direction and wind frequency, occur depending on the season. For example, every three months from the start of construction to each season changes The state of the building is modeled.

  In the initial construction plan of this building, it is assumed that building A is constructed first, building B is constructed next, and building C is constructed last. Specifically, as shown in Fig. 3, construction started in March of the first year and the 6th floor of Building A was built within 3 months until May, and the next 3 months (June to August) ) Until the 12th floor of the A building, the next 3 months (September to November) will be built up to the 17th floor of the A building, and the next 3 months (December to February) A three-dimensional model that is planned so that the third floor of the B building is constructed as the building is completed is generated. After that, a three-dimensional model has been generated in which the building B is completed by the 21st month from the start of construction and the building C is completed in the 3 months from the 22nd to the 24th month.

  After the modeling step S320, for example, meteorological information data held by the Japan Meteorological Agency or the like is associated with the completed three-dimensional model data based on the construction time of each stage (weather information associating step S330). This weather information data is, for example, that the wind blows from the south and the north in the north-south direction during the three months (March to May) at the construction site, and south from the spring in the summer (June to August). The frequency of wind blows is high. In autumn (September to November), the north wind blows more frequently than the south wind in the north and south, and the north wind blows in winter (December to February). It is weather information data about the wind that is high. For this reason, the spring weather information data is associated with the three months from the start of construction, and the summer weather information data is associated with the three months of 4-6 months. Meteorological information data for 24 months from the start of construction. At this time, weather information data other than wind such as typhoon, heavy rain, heavy snow is also associated (S340), and in the construction plan, if there is a possibility that weather such as typhoon, heavy rain, heavy snow may have a great influence, The construction plan is reviewed, and three-dimensional model data that models the state of the building at each stage is generated based on the revised construction plan (review steps S322 and S330). At this time, as a windproof measure, a measure such as a general temporary enclosure is incorporated.

FIG. 4 is a flowchart showing processing from simulation to selection of an optimal construction plan.
Next, based on the three-dimensional model data of each stage based on the construction plan and the weather information data on the wind associated with each stage, for example, using the wind environment simulator “Zephyrus” (registered trademark), the construction process The wind environment at each stage is simulated (simulation step S361). FIG. 5 is a diagram for explaining an example of a result of simulating the wind environment with “Zephyrus” (registered trademark), and FIG. 5A is a diagram showing the wind environment in a state where no wind protection measures are taken. FIG. 5B is a diagram showing a wind environment in a state in which a windproof measure is taken. By using the wind environment simulator, as shown in FIG. 5, by confirming the change in the wind environment such that the weak wind region 5 (dark region) is formed by providing the windbreak wall 3 in the passage 1. Is possible.

  FIG. 6 is a diagram illustrating an example of a result of simulation based on three-dimensional model data based on an initial construction plan and weather information data regarding wind. In FIG. 6, the direction of the wind and the frequency of wind blowing are indicated by arrows, the strong wind area is indicated by fine pitch hatching, and the weak wind area is indicated by hatching with a coarse pitch. In addition, the windproof countermeasures need to be examined are marked with ★ and the windbreak countermeasures are colored in gray.

  As shown in Fig. 6, three months after the start of construction, that is, during spring, slightly strong wind areas are generated at the four corners of Building A, which is constructed up to the 6th floor, and the wind direction changes during the summer when the construction is conducted up to the 12th floor. As a result, a strong wind region is generated at the two corners south of the building A, but a simulation result is obtained that does not affect the outside of the site. In the fall and winter of the first year, a simulation result has been obtained that a strong wind region blows in the north-south direction on the east and west sides of building A, which is at least 13 stories high, and the strong wind affects the outside of the site. . At this time, the strong wind region generated on the east side of the A building is the construction planned site of the C building.

  In the spring of the second year, when building B is built to about 1/3 height, a strong wind region is generated on the east side of building B in addition to the east and west sides of building A. The strong wind area on the east side of Building B does not affect the outside of the site. In the summer and autumn of the second year, when the height of building B exceeds half, the east and west sides of building A, building B, that is, the west side of building A, the east side of building B, and buildings A and B A strong wind region occurs during At this time, the planned construction site between the A building and the B building, that is, the C building is a particularly strong wind region.

  And in the winter of the second year, when building C is completed and planting is provided on the west side of building A and on the east side of building B, there is still a strong wind area around the planted area. Simulation results have been obtained that there is an area but does not affect the outside of the site. In addition, the simulation results show that there are 19 windproof measures that need to be examined in the construction process. At this time, since the preset target value of 12 points or less necessary for windbreak countermeasures has not been achieved (S362), the simulation result is analyzed (S363), and improvement measures such as strong wind generation and windbreak planting are examined ( S364-S366).

  FIG. 7 shows a countermeasure against an enclosure wall as an example of a windbreak countermeasure. FIG. 7A shows a normal enclosure wall, and FIG. 7B shows an example in which the enclosure wall is extended upward. FIG.7 (c) is a figure which shows the surrounding wall which inclined the upper part to the construction site side.

  As a windbreak countermeasure, for example, the height is increased as shown in FIG. 7B compared to the normal enclosure wall 10 shown in FIG. 7A, or the enclosure wall is shown in FIG. 7C. The upper part 10a of 10 may be inclined toward the construction site and the wind may be wound back to suppress the diffusion of dust. Moreover, based on the result of the simulation by the environmental simulation system at the construction site and the environmental simulation method at the construction site, it is possible to examine a dust-proof measure that suppresses the diffusion of dust and the like.

  FIG. 8 shows an example of dust-proof measures at the time of construction. FIG. 8 (a) is an example in which a rubber skirt is installed at the foot of the open / close gate, and FIG. 8 (b) is to construct a temporary enclosure gate. FIG. 8 (c) shows an example in which a temporary enclosure gate is provided in two directions, and FIG. 8 (d) is provided with a dust collecting device at a position that becomes a strong wind region. It is a figure which shows the example. FIG. 9 is a diagram showing an example of a dust-proof measure at the time of dismantling, FIG. 9 (a) is a diagram showing a normal enclosure wall at the time of dismantling work, and FIG. 9 (b) is an operation interrupted. It is a figure which shows the state at the time of a strong wind which has a possibility, and FIG.9 (c) is a figure which shows the surrounding wall which inclined the upper part to the dismantling site side.

  As a dustproof measure, as shown in FIG. 8 (a), a rubber skirt 16 is provided at the foot of the open / close gate 13 serving as an entrance to the enclosed construction site, or FIG. 8 (b) and FIG. 8 (c). In this way, the position and orientation of the temporary enclosure gate 14 are changed. Specifically, as shown in FIG. 8 (b), a temporary enclosure gate 14 is provided at a position behind the building being constructed, or a rectangular enclosure wall 10 is formed as shown in FIG. 8 (c). Temporary enclosure gates 14a and 14b are provided on two orthogonal wall surfaces, respectively, avoiding the use of temporary enclosure gates (main gates) 14a intersecting with the wind direction, and temporary enclosure gates (sub-gates) 14b provided in parallel with the wind direction. Is used. At this time, as shown in FIG. 8D, if the dust collecting device 18 is provided on the enclosure wall 10 intersecting with the wind direction, it is possible to take not only a windproof measure but also a dustproof measure.

  Moreover, in the case of demolition work, there is a possibility that dust is diffused in a normal enclosure wall 10 as shown in FIG. 9A when a strong wind blows as shown in FIG. 9B. As shown in FIG. 9 (c), a soundproof panel or soundproof sheet is inclined to the dismantling site side at the upper part 10a of the surrounding wall 10 at a position higher than the top floor, and a scattering prevention net is provided to suppress the diffusion of dust. .

  FIG. 10 is a diagram showing the difference in wind environment depending on the construction order, FIG. 10 (a) is a diagram showing the wind environment at the time of completion, and FIG. 10 (b) is when constructing the building A first. FIG. 10C is a diagram showing the wind environment when building B first.

  As shown in FIGS. 10 (b) and 10 (c), it is possible to recognize before construction that the range of the strong wind area can be reduced by constructing B building before building A. . That is, since the wind environment changes depending on the order of the buildings to be constructed, it is conceivable to change the order of the buildings to be constructed based on the simulation results as a windproof and dustproof measure.

  FIG. 11 is a diagram showing the difference in wind environment due to rebuilding, FIG. 11 (a) is a diagram showing the wind environment before rebuilding, and FIG. 11 (b) is a diagram showing the wind environment after rebuilding. Yes, FIG. 11C is a diagram showing the wind environment during the rebuilding work.

  As shown in FIG. 11 (a) and FIG. 11 (b), there is no large strong wind region before and after the rebuilding, but during the rebuilding as shown in FIG. 11 (c) It is possible to recognize by simulation before the rebuilding work that the position of this building, that is, a large strong wind region is generated between the building under construction and one existing building adjacent thereto.

  In the present embodiment, it was confirmed in the result of the initial simulation that a strong wind region is generated around the building when a building that protrudes greatly is created. A construction plan is formulated, and new three-dimensional model data in which the state of the building at each stage is modeled based on the formulated construction plan is generated (S322). The new three-dimensional model data generated also at this time is the state of the building at each stage of the building construction process based on the new construction plan, along with the model of the surrounding block of the building.

FIG. 12 is a diagram showing the concept of 3D model data based on a new construction plan.
Specifically, as shown in Fig. 12, the new 3D model data starts in March of the first year, and in the three months until May, the buildings A and B etc. are parallel to the third floor. In the next three months, A and B will be built up to the 4th floor, and C will be completed between A and B. After that, a three-dimensional model was planned in which A and B buildings were constructed with almost the same number of floors, and A and B buildings were completed within two years from the start of construction.

  After the new 3D model data modeling step (S322), the completed new 3D model data is associated with the same weather information data as at the beginning based on the construction time of each stage (model weather response step S330). Based on the new three-dimensional model data at each stage based on the construction plan and the weather information data on the wind associated with each stage, the wind environment simulator “Zephyrus” (registered trademark) is used. The wind environment at each stage is evaluated (simulation step S361).

  FIG. 13 is a diagram illustrating an example of a result of simulation based on new three-dimensional model data and weather information data related to wind. As shown in Fig. 13, three months after the start of construction, that is, during spring, slightly strong wind areas are generated at the four corners of Building A and Building B up to the third floor, and Building A and Building B are built up to the fourth floor. During the summer when building C is completed, it is difficult for wind to pass between building A and building B due to building C, so a strong wind region will occur on the west side of building A and the east side of building B, but the direction of the wind will change. As a result, a strong wind region is generated in the south corner of the A building and the B building, but a simulation result is obtained that does not affect the outside of the site. And until the fall of the first year, when the height from building A to building C is almost the same, the autumn wind blows from the north and south sides, so along the building on the west side of building A and the east side of building B The simulation results show that a strong wind region occurs but does not affect the outside of the site. After that, from the first year winter to the second year winter, the buildings A and B protrude upward from the building C, and the strong wind region changes according to the wind direction and the frequency of wind that change according to the season. As a result, a simulation result has been obtained that the wind is generated on the west side of building A and on the east side of building B, and the strong wind affects the outside of the site. Further, in the simulation using the new three-dimensional model data, a simulation result is obtained that the generation of a strong wind region between the A building and the B building can be suppressed. In addition, the simulation result of this time shows that there are twelve windbreak countermeasures requiring examination points in the construction process. At this time, since the preset target value of 12 points or less necessary for windproof measures has been achieved, construction is started (S370, S380). At this time, if the target value has not been achieved, the simulation result is analyzed again (S363), further windproof measures are examined (S364 to S366), new three-dimensional model data is generated (S322), and the generated new A simulation is executed based on the three-dimensional model data and the wind information (S361).

  At this time, for the start of the construction, for example, examination of a place suitable for wind power generation during construction (S367), examination of a strong wind notification system, etc. (S368), examination of a communication tool using wind (S369), etc. It is possible to select an optimal construction plan that takes into account the wind environment.

  According to the environmental simulation system of the construction site of the present embodiment, the 3D model data models the surrounding block of the building to be constructed and the state at each stage of the construction process of the building in stages. Therefore, it is possible to grasp the state of the building that is included in the surrounding block and changes in stages as a three-dimensional model. At each stage of the three-dimensional model data, the weather information data correlated based on the construction period of each stage is used to simulate the influence of the weather on the building and the surrounding block (S361). It is possible to confirm in advance the influence of the weather at each stage of the building and the surrounding city block. That is, it is possible to confirm in advance the influence of the weather environment of the construction site under construction.

  Moreover, when the simulation result (S361) and the preset target value are not achieved, the simulation result is analyzed (S363), and improvement measures such as strong wind generation and windbreak planting are examined (S364 to S366). Then, new three-dimensional model data is generated (S322), and the new three-dimensional model data and the weather information data are associated with each other based on the construction time of each stage and simulated (S361). It is possible to confirm the environmental impact of the changes made. For this reason, for example, it is possible to easily confirm in advance whether or not the countermeasure is appropriate by applying the countermeasure for the environment to the three-dimensional model data as a change.

  In addition, the generation of new 3D model data (S322) and the simulation of new 3D model data (S361) are repeated until reaching a preset target value. Can be suppressed to a target value set in advance.

  In the above-described embodiment, the weather information data to be simulated is used as information about the wind, and the example of confirming the wind environment of the construction site in advance for realizing the construction site suitable for the wind environment has been described. However, the present invention is not limited to this. Absent. For example, based on information such as dust and snowdrift and three-dimensional model data, it is possible to confirm the influence of dust and snowdrift on the building and the surrounding block.

  The above embodiment is for facilitating the understanding of the present invention, and is not intended to limit the present invention. The present invention can be changed and improved without departing from the gist thereof, and it is needless to say that the present invention includes equivalents thereof.

DESCRIPTION OF SYMBOLS 1 Passage 3 Windbreak wall 5 Light wind area 10 Enclosure wall 10a Upper part of enclosure wall 12 Sleeve wall 13 Opening and closing gate 14 Temporary enclosure gate 14a Temporary enclosure gate (main gate)
14b Temporary enclosure gate (sub gate)
16 Rubber skirt 18 Dust collector

Claims (5)

A modeling step for generating three-dimensional model data obtained by modeling a surrounding block of a plurality of buildings to be constructed and a state in each stage of the construction process of the plurality of buildings based on the three-dimensional data;
Weather information associating step for associating based on the weather information data corresponding to the construction period of the plurality of buildings in the surrounding city block to said three-dimensional model data including the construction site of the plurality of building the in construction time of each stage,
On the basis of the said associated with the three-dimensional model data weather information data, simulation step for simulating the influence of weather for the plurality of buildings and the surrounding city block in each stage and,
A construction order determination step for determining a construction order of the plurality of buildings based on the simulation result,
A construction site environmental simulation method characterized by comprising: A modeling process for generating 3D model data obtained by modeling the surrounding block of the site constructed inside the enclosure wall and the state at each stage of the construction process of the site based on the 3D data;
A meteorological information associating step for associating the three-dimensional model data with the meteorological information data corresponding to the construction period of the site in the surrounding block including the site , based on the construction time of each stage ;
On the basis of the said associated with the three-dimensional model data weather information data, simulation step for simulating the influence of weather for the site and the surrounding city block in each stage and,
Based on the result of the simulation, a dust-proof measure step for inclining the upper part of the enclosure wall toward the site,
A construction site environmental simulation method characterized by comprising: A modeling process for generating 3D model data obtained by modeling the surrounding block of the site constructed inside the enclosure wall and the state at each stage of the construction process of the site based on the 3D data;
A meteorological information associating step for associating the three-dimensional model data with the meteorological information data corresponding to the construction period of the site in the surrounding block including the site , based on the construction time of each stage ;
On the basis of the said associated with the three-dimensional model data weather information data, simulation step for simulating the influence of weather for the site and the surrounding city block in each stage and,
Based on the simulation result, a dust-proof measure step for planning the entrance and exit of the enclosure into the site,
A construction site environmental simulation method characterized by comprising: A modeling process for generating 3D model data obtained by modeling the surrounding block of the building to be constructed and the state of each stage of the building construction process based on the 3D data;
A weather information associating step for associating the three-dimensional model data and the weather information data corresponding to the construction period of the building in the surrounding block including the construction site of the building based on the construction time of each stage; and
Based on the weather information data associated with the three-dimensional model data, a simulation step of simulating the influence of weather on the building and the surrounding block in each stage,
Have
Based on the simulation result, the three-dimensional model data is changed to new three-dimensional model data,
Corresponding the new three-dimensional model data and the weather information data based on the construction time of each stage, to simulate the influence of the weather on the building and the surrounding block in each stage,
The generation of the new 3D model data and the simulation for the new 3D model data are repeated until reaching a preset target value,
A construction site environmental simulation method characterized by selecting a construction plan in consideration of the weather information . A construction site environmental simulation method according to claim 4,
The construction site environmental simulation method characterized in that the construction plan is examination of a place suitable for wind power generation during construction, examination of a strong wind notification system, or examination of a communication tool using wind.