Proses pemindahan pengguna ketika situasi kecemasan amat penting seiring dengan pembangunan struktur bertingkat yang mampan. Proses memindahkan pengguna adalah mencabar kerana melibatkan perkara-perkara luar kawalan seperti tingkahlaku pengguna dan faktor dinamik kemalangan. Kajian ini dilaksanakan bagi merancang dan menguji proses pemindahan pengguna didalam persekitaran 3D. Ia merangkumi tiga fasa iaitu fasa integrasi data, pembangunan dan pengujian topologi dan analisa simulasi. Pengujian kaedah integrasi model 3D BIM kepada 3D GIS dilakukan dengan menggunakan kaedah Revit ke Feature Manipulation Engine (FME) dan seterusnya ke Multipatch Shapefile dipilih sebagai kaedah terbaik kerana memenuhi keperluan analisa kecemasan. Seterusnya, jaringan topologi kekisi dibina dan diuji melalui ujian ketersediaan dan ujian ketepatan. Purata kadar ketersediaan akses dikenalpasti melebihi 12% manakala purata keralatan dikenalpasti sebanyak 3.18%. Pengiraan jarak ke akses keluar dan saiz kekisi 0.38m digunakan sebagai input parameter dalam fasa ketiga. Tiga parameter digunakan iaitu kelajuan, kapasiti pengguna dan pemilihan akses diuji dalam lapan simulasi yang berbeza. Hasil simulasi diperincikan kedalam dua faktor iaitu masa dan ruang kritikal. Faktor masa mengupas kesan kapasiti pengguna dan pemilihan akses terhadap masa. Kesan kapasiti pengguna didapati semakin besar apabila tempoh masa pemindahan pengguna bertambah. Kaedah pembahagian akses dikenalpasti sebagai kaedah terbaik untuk memindahkan pengguna dengan purata 17% lebih pantas berbanding kaedah lain. Faktor ruang kritikal melibatkan pengenalpastian ruang kritikal didalam bangunan melalui peta haba dan teori Level of Service. Pengenalpastian ruang kritikal dikenalpasti berpunca daripada akses yang berkelebaran kurang dari 1.5 meter bagi setiap aras. Pengujian pelebaran akses diuji dan dibuktikan mampu menambahbaik aliran pemindahan pengguna dalam kajian ini.

Kata kunci: 3D, akses, BIM, GIS, kecemasan, topologi

The process of evacuating users in emergency management is very important, in line with the development of a sustainable multi-level structure. It is challenging because they are tied to things beyond control such as user behavior and dynamic factors of an accident. This study is conducted to design and evaluate the user evacuation process in a 3D environment. It involves three phases namely data integration phase, topology development and testing, and simulation analysis. Methods of integrating 3D BIM models into 3D GIS were tested and the integration method from Revit to Feature Manipulation Engine (FME) to Multipatch Shapefile was chosen as the best method because it met the needs of emergency analysis. Next, the topology network is developed and tested through availability and accuracy test. The average availability access is more than 12% while the error rate detected is 3.18%. The distance measured for the nearest exit and the 0.38m lattice size is used as a parameter input in the third phase. Three parameters namely speed, user capacity and access selection were tested in eight different simulations. The simulation results are summarized into two factors: time and space critical. Time factors elaborate on the impact of user capacity and selection of access towards time. The effect of user capacity would be greater as the duration of user evacuation increases. The divide access method was identified as the best way to evacuate users on average of 17% faster than other methods. Critical space factors discussed the identification of critical spaces through heat maps and the Level of Service theory. The critical spaces were identified due to access with less than 1.5 meters width at each level. Through access widening testing has proven can improve user evacuation flow in this study.

Keywords: 3D, access, BIM, emergency, GIS, topology

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