Optimization and Combination of Green Building Design in Architectural Design
DOI:
https://doi.org/10.53469/jtpss.2023.03(07).05Keywords:
Architectural design, Green buildings, Optimization and integrationAbstract
With the advancement of urbanization in China, environmental pollution and resource and energy consumption are becoming increasingly serious. All sectors of society are beginning to realize the problems faced in developing a "green" economy and environmental protection, reasonably reflecting the design principles and goals of green buildings, and fully implementing the concept of green environmental protection. In order to maintain a good relationship between the construction site and design work, and better achieve the original goals, it is necessary to provide open and environmentally friendly facilities for the construction site, adhere to the concept of sustainable development, seek the internal driving force of change, coordinate design work, make more use of civil engineering, reduce resource and energy consumption, and reduce its adverse impact on the environment.
References
Gu Shaogang, Chen Xianbo, Sun Haiyang, Wang Jian. Discussion on the Optimization of Green Building Technology in Architectural Design [J]. Intelligent Building and Smart City, 2021 (08): 114-115.
Wang Xinyi. Analysis of the Optimization and Combination of Green Building Technology in Architectural Design [J]. Huazhong Architecture, 2019, 37 (06): 55-57.
Zhou Yirong. Key points and application of green building technology optimization in architectural design [J]. Urban Residential, 2021, 28 (12).
Lili J, Minglu M. Analysis of Maritime Traffic Safety Based on Intrinsic Safety Theory[C]//Journal of Physics: Conference Series. IOP Publishing, 2021, 1827(1): 012040.
Bi J, Gao M, Zhang W, et al. Research on Navigation Safety Evaluation of Coastal Waters Based on Dynamic Irregular Grid[J]. Journal of Marine Science and Engineering, 2022, 10(6): 733.
Li L, Lu W, Niu J, et al. AIS data-based decision model for navigation risk in sea areas [J]. The Journal of Navigation, 2018, 71(3): 664-678.
Han Y, Zhen X, Huang Y. Hybrid dynamic risk modelling for safety critical equipment on offshore installations [J]. Process Safety and Environmental Protection, 2021, 156: 482-495.
Vassalos D. A Pioneer of Maritime Safety [J]. Ships and Offshore Structures, 2020, 15(5): 462-467.
Ozbas B. Safety risk analysis of maritime transportation: review of the literature [J]. Transportation research record, 2013, 2326(1): 32-38.
Park C, Kontovas C, Yang Z, et al. A BN driven FMEA approach to assess maritime cybersecurity risks [J]. Ocean & Coastal Management, 2023, 235: 106480.
