شبيه سازي انتشار دود ناشي از آتش سوزي در ساختمان هاي بلند مرتبه با استفاده از مدل‌ سه‌بعدي توليد شده از داده‌هاي كاداستر دو‌بعدي تفكيك آپارتمان

Simulation of Smoke Emission from Fires in High-Rise Buildings Using the 3D Model Generated from 2-Dimensional Cadastral Data

در اختيار داشتن مدل سه‌بعدي از ساختمان‌هاي با تعداد طبقات بالا، در مواقع اضطراري همچون رخداد آتش‌سوزي، نقش بنيادي و راهبردي در مديريت بحران و كاهش خسارات دارد. درحالي‌كه ايجاد مدل سه‌بعدي ساختمان‌هاي بلند، همواره با كمبود اطلاعات موردنياز روبرو بوده است، داده‌هاي دوبعدي تفكيك آپارتمان، به‌عنوان منبع باارزش، كم‌هزينه‌اي و در دسترس مي‌تواند مورداستفاده قرار گيرد. با به‌كارگيري اين داده‌ها و استفاده از ابزارهاي مدل‌سازي سه‌بعدي، مي‌توان گامي مؤثر در توليد مدل سه‌بعدي ساختمان‌ها، به‌ويژه ساختمان‌هاي بلند‌مرتبه در شهرها برداشت. هنگام بروز آتش‌سوزي در ساختمان، دود يكي از عوامل اصلي تهديد‌كننده سلامت افراد خواهد بود كه حركت و انتشار آن در قسمت‌هاي گوناگون ساختمان، متأثر از شرايط طراحي داخلي و معماري ساختمان است. ازاين‌رو شبيه‌سازي رايانه‌اي نحوه انتشار دود در ساختمان، تحت سناريوهاي گوناگون، مي‌تواند در هنگام بروز آتش‌سوزي، كمك شاياني در فرايند تصميم‌گيري مديران بحران و كاهش تلفات انساني، ايفا نمايد. در اين تحقيق، ابتدا پلان دوبعدي يك ساختمان بلندمرتبه واقع در تهران، به‌صورت خودكار از داده‌هاي اخذشده از سامانه نقشه‌هاي تفكيكي اداره ثبت، ايجاد گرديد. سپس با بهره‌گيري از نرم‌افزار CityEngine، مدل سه‌بعدي ساختمان با جزئيات مناسب توليد شد. درنهايت با به‌كارگيري مدل سه‌بعدي ايجادشده، شبيه‌سازي انتشار دود در ساختمان موردنظر در هفت سناريو متفاوت، در نرم‌افزار PyroSim انجام گرفت. نتايج مؤيد قابليت‌هاي مناسب مدل سه‌بعدي ساخته‌شده از داده‌هاي دوبعدي تفكيك آپارتمان، براي شبيه‌سازي و تحليل سناريوهاي گوناگون انتشار دود در ساختمان‌هاي بلند است

Having a 3-Dimensional model of high-rise buildings can be used in disaster management such as fire cases to reduce casualties. The fundamental dilemma in 3D building modeling is the unavailability of suitable data sources. However, available cadastral 2D maps could be used as low-cost and attainable resources for 3D building modeling. Smoke will be a great threat to peoplechr('39')s health during a fire in a building and its movement and diffusion in different parts of the building are affected by the architectural design of the building. Computer simulation can be utilized to investigate smoke movement and its emanated toxic gases under various scenarios which can play a significant role in decision making during a fires incident event to reduce human casualties. In this research, at first, 2D cadastral maps of a high-rise building located at Tehran were utilized to produce a 3D model of building with adequate details in CityEngine. Next, smoke emission in the building was simulated under seven scenarios, using PyroSim software. The two-dimensional data of apartment separation is readily available and at the lowest cost. Using some tools and techniques in spatial information systems, making it possible to utilize this data to implement a three-dimensional model of a building with details to simulate the spread of smoke from fires. The process adopted in this study made it possible to use a two-dimensional floor plan to produce a three-dimensional model of the building at the LoD4. The results confirm the appropriateness of the constructed 3D model to simulate smoke emission under various scenarios in the high-rise building. This result shows the effect and importance of smoke transfer routes, both inside and outside the building, on the emission of toxic gases. The results show that ensuring that the ducts are closed is one of the factors controlling the spread of smoke to other floors. Flue gutters and ducts are among the most important routes for emitting smoke in high-rise buildings. The simulation results of Scenario 4 show that 40 seconds after the start of the fire, the toxic fumes spread through the stairs at all top floors of the building. Although data from 2D cadastral maps can be used to create a three-dimensional model of a building, these data have shortcomings. The part related to the texture of the map features is faced with a lack of information such as the thickness of the walls, the type of used materials, the exact location of the components (doors and windows) on the walls, and so on. These factors affect the smoke emission simulation results. As a result, development of a three-dimensional model of the building containing more detailed information about the specifications and materials used in the walls and various parts of the building needs to be considered in future research. The smoke emission simulation results can also be used in a variety of applications, including emergency evacuation modeling in the event of a fire in a building, along with the inclusion of other information such as number and physical characteristics of residents in different parts of the building.