大跨度建筑预应力混凝土板的多目标绿色设计模型

IF 2.7 4区工程技术 Q2 CONSTRUCTION & BUILDING TECHNOLOGY

Architectural Engineering and Design Management Pub Date : 2022-11-19 DOI:10.1080/17452007.2022.2147897

Jewoo Choi, D. Hong, Seung Hyeong Lee, Ha Yeon Lee, Taehoon Hong, Dong-Eun Lee, H. Park

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引用次数: 1

摘要

摘要预应力混凝土（PC）板是大跨度楼板建筑中最常用的板体系之一。为了同时降低施工成本和环境影响，大跨度结构中PC板的绿色设计模型是必要的。本文建立了预应力混凝土板的多目标绿色设计模型（MGDPCS），以最大限度地减少PC板的二氧化碳排放和施工成本。MGDPCS针对输入的PC板尺寸和荷载，使用非支配排序遗传算法（NSGA-II）提供了优化的PC板厚度、钢筋直径和屈服强度、钢筋束尺寸和屈服强度。此外，利用该模型分析了PC板跨度长短边和钢筋束的变化对施工成本和环境影响的影响。因此，我们开发了两个指标，即环境和经济得分以及生态友好系数，来评估使用MGDPCS的实用绿色设计的性能。为了验证MGDPCS的适用性，将该模型应用于一栋板跨度为10m的六层工业建筑的PC板设计分析 × 10米。结果表明，基于二氧化碳排放和成本的降低，MGDPCS获得的最佳设计分别比现有的建筑楼板设计好8.12%和13.62%。

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Multi-objective green design model for prestressed concrete slabs in long-span buildings

ABSTRACT Prestressed concrete (PC) slab using tendons is one of the most frequently used slab systems in the construction of buildings with long-span slabs. To simultaneously minimize the construction cost and the environmental impact, a green design model for PC slabs in long-span structures is necessary. In this paper, a multi-objective green design model for prestressed concrete slabs (MGDPCS) was developed to minimize both CO2 emissions and the construction costs of PC slabs. MGDPCS provides the optimized PC slab thickness, diameter and yield strength of the rebar, size and yield strength of the tendon using the Non-dominated Sorting Genetic Algorithm (NSGA-II) for the input PC slab size and load. Furthermore, the effects of changes in the long- and short-side of span and tendons of PC slabs on construction costs and environmental impact are analyzed using the proposed model. Accordingly, we developed two indicators, that is, the environmental and economic scores and the eco-friendly coefficient, to evaluate the performance of the practical green designs using MGDPCS. To verify the applicability of MGDPCS, the model was applied used to analyze the designs of PC slabs in an actual six-story industrial building with a slab span of 10 m × 10 m. The results showed that the optimal designs obtained from MGDPCS outperformed existing slab designs for buildings by 8.12% and 13.62% based on the reductions in CO2 emissions and costs, respectively.

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来源期刊

Architectural Engineering and Design Management Multiple-

CiteScore

5.80

自引率

3.40%

发文量

期刊介绍： Informative and accessible, this publication analyses and discusses the integration of the main stages within the process of design and construction and multidisciplinary collaborative working between the different professionals involved. Ideal for practitioners and academics alike, Architectural Engineering and Design Management examines specific topics on architectural technology, engineering design, building performance and building design management to highlight the interfaces between them and bridge the gap between architectural abstraction and engineering practice. Coverage includes: -Integration of architectural and engineering design -Integration of building design and construction -Building design management; planning and co-ordination, information and knowledge management, vale engineering and value management -Collaborative working and collaborative visualisation in building design -Architectural technology -Sustainable architecture -Building thermal, aural, visual and structural performance -Education and architectural engineering This journal is a valuable resource for professionals and academics (teachers, researchers and students) involved in building design and construction, including the following disciplines: -Architecture -Building Engineering -Building Service Engineering -Building Physics -Design Management and Design Coordination -Facilities Management Published papers will report on both fundamental research dealing with theoretical work and applied research dealing with practical issues and industrial innovations. In this way, readers explore the interaction between technical considerations and management issues.