Sustainable High-Rise Buildings : Design, Technology, and Innovation / / Al-Kodmany, Du and Ali [Eds]
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| Autore: |
Al-Kodmany Kheir
|
| Titolo: |
Sustainable High-Rise Buildings : Design, Technology, and Innovation / / Al-Kodmany, Du and Ali [Eds]
|
| Pubblicazione: | Stevenage : , : Institution of Engineering & Technology, , 2022 |
| ©2022 | |
| Edizione: | 1st ed. |
| Descrizione fisica: | 1 online resource (531 pages) |
| Disciplina: | 720.47 |
| Soggetto topico: | Sustainable buildings - Design and construction |
| Sustainable buildings | |
| Sustainable architecture | |
| Altri autori: |
DuPeng
AliMir M
|
| Nota di contenuto: | Intro -- Title -- Copyright -- Contents -- About the editors -- The Institution of Engineering and Technology -- About CTBUH -- Foreword -- Introduction -- Part I: Architecture -- 1 Designing sustainable tall buildings -- 1.1 The idea of the sustainable tall building or skyscraper -- 1.2 Ecosystem characteristics and attributes -- 1.3 Preliminary design studies for technical, biological, and augmented solutions -- 1.3.1 Ecosystem's biotic-abiotic structure -- 1.3.2 Ecosystem biodiversity -- 1.3.3 Ecosystem connectivity and nexus -- 1.3.4 Provision of ecosystem services -- 1.3.5 Ecosystem biointegration -- 1.3.6 Ecosystem responsiveness to climate -- 1.3.7 Ecosystem's use and cycling of material -- 1.3.8 Ecosystem hydrology -- 1.3.9 Ecosystem symbiosis -- 1.3.10 Ecosystem homeostasis -- 1.3.11 Ecosystem's food production -- 1.3.12 Ecosystem's succession -- 1.4 Building physics and modeling -- 1.5 Conclusion -- References -- 2 Skybridges: bringing the horizontal into the vertical realm -- 2.1 Introduction -- 2.1.1 Purpose of the research -- 2.1.2 Issues under exploration -- 2.1.3 Research objectives -- 2.1.4 Research methodology -- 2.2 Classification and analytical criteria -- 2.2.1 Skybridge typologies -- 2.2.2 Measurement and calculation methodology -- 2.3 Analysis -- 2.3.1 Ownership/management -- 2.3.2 Usage/programming -- 2.3.3 Access/security -- 2.3.4 Structural engineering -- 2.3.5 MEP engineering -- 2.3.6 Fire engineering/evacuation -- 2.3.7 Construction -- 2.3.8 Interiors -- 2.3.9 Evaluation: qualitative -- 2.3.10 Evaluation: quantitative -- 2.4 Urban-scale considerations: skybridge networks in practice -- 2.4.1 Hong Kong skybridge network -- 2.4.2 Atlanta: Peachtree Center -- 2.4.3 Learning from the Atlanta and Hong Kong skybridge networks -- 2.5 3-D urban growth -- 2.6 Conclusion -- Acknowledgment -- References. |
| 3 Recent developments in sustainable environmental systems of tall buildings -- 3.1 Introduction -- 3.2 Goals and objectives -- 3.3 Methodology -- 3.4 Environmental systems -- 3.5 Multi-functional tall buildings -- 3.6 Bioclimatic design -- 3.7 Sustainable environmental services and strategies -- 3.7.1 Natural ventilation -- 3.7.2 Daylight harvesting and artificial lighting -- 3.7.3 Heating and cooling -- 3.7.4 Combined heat and power -- 3.8 Integrated systems -- 3.8.1 Integration of intelligent building systems -- 3.9 Case studies -- 3.9.1 4 Times square -- 3.9.2 Pearl River Tower -- 3.9.3 New York Times Headquarters -- 3.9.4 Shanghai Tower -- 3.9.5 Leeza SOHO Tower -- 3.9.6 Salesforce Transit Tower and Transit Center -- 3.9.7 340 On the Park -- 3.9.8 30 St. Mary Axe -- 3.9.9 Pertamina Energy Tower -- 3.10 Discussion -- 3.11 Sustainable cities and environmental infrastructures -- 3.11.1 New Songdo City -- 3.12 Conclusion -- References -- 4 Assessment of tall buildings' environmental sustainability: frameworks and tools -- 4.1 Introduction -- 4.2 Assessment of tall building sustainability -- 4.2.1 Social and economic sustainability -- 4.2.2 Environmental sustainability -- 4.3 Tall buildings and impacts on the environment -- 4.3.1 Structural systems -- 4.3.2 Whole building -- 4.4 Uncertainties and limitations in the assessment of impacts -- 4.5 Conclusion -- References -- 5 Curtain walling resiliency for tall buildings: standards, testing, and solutions -- 5.1 Introduction -- 5.2 Impact resiliency of curtain walls: testing standards -- 5.2.1 Impact testing of curtain walls -- 5.2.2 Flying debris impact testing of curtain walls -- 5.3 Windborne debris resiliency of curtain walls and tall building façade design -- 5.3.1 Characteristics of flying debris-resilient curtain wall solutions. | |
| 5.4 Local windborne debris-resistant curtain walls: the aerodynamic of windborne debris -- 5.4.1 Literature review -- 5.4.2 Roof tiles -- 5.4.3 Debris failure in extreme wind events -- 5.4.4 Future work -- 5.5 Findings -- 5.6 Conclusion -- References -- 6 Sustainability meets performance with tall timber buildings -- 6.1 Why tall timber? -- 6.2 Carbon footprint and forest health -- 6.3 Embodied carbon and LCA -- 6.4 Global precedents and US code changes -- 6.5 Mass timber products and performance -- 6.6 Fire-resistance ratings and timber encapsulation -- 6.6.1 Contribution of mass timber to FRR -- 6.6.2 Fire protection of connections -- 6.6.3 Fire protection of concealed spaces -- 6.6.4 Fire protection of shaft enclosures -- 6.6.5 Noncombustible protection of mass timber shaft walls -- 6.6.6 Other considerations -- 6.7 Acoustic performance in tall timber -- 6.7.1 Basics of acoustics and code requirements -- 6.7.2 Unique mass timber acoustics considerations -- 6.8 Grid selection and cost optimization -- 6.8.1 Grid selection -- 6.8.2 Mass timber panel spans -- 6.8.3 Grid options -- 6.8.4 Manufacturer input -- 6.9 Market drivers for tall wood -- 6.9.1 Innovation and aesthetic appeal -- 6.9.2 Cost savings -- 6.9.3 Healthy buildings -- 6.10 Opportunities, challenges, and next steps -- 6.11 Conclusion -- References -- Part II: Engineering -- 7 Sustainable structural design of tall buildings -- 7.1 Introduction -- 7.2 Tubular systems for sustainable structures -- 7.2.1 Framed tube and bundled tube -- 7.2.2 Braced tube -- 7.2.3 Braced megatube -- 7.2.4 Diagrids -- 7.2.5 Optimal lateral stiffness distribution for tubular structures -- 7.3 Outrigger structure -- 7.3.1 Structural design and performance of outrigger system -- 7.3.2 Comparative premium for height -- 7.4 Hybrid structural systems -- 7.4.1 Supertalls with mixed structural systems. | |
| 7.4.2 Lateral stiffness distribution alternatives in mixed systems -- 7.5 Superframed conjoined towers for sustainable megatalls -- 7.5.1 Superframed conjoined towers with single-link structures -- 7.5.2 Superframed conjoined towers with multiple-link structures -- 7.6 Conclusion -- References -- 8 Core design and space efficiency in contemporary supertall office buildings -- 8.1 Introduction -- 8.2 Literature review -- 8.3 Methodology -- 8.4 Design considerations for supertall office buildings -- 8.4.1 Core planning -- 8.4.2 Structural systems and structural materials -- 8.4.3 Lease span and floor-to-floor height -- 8.4.4 Space efficiency -- 8.5 Discussion -- 8.5.1 Structural system -- 8.5.2 Structural material -- 8.5.3 Core planning -- 8.5.4 Space efficiency -- 8.6 Conclusion -- Glossary -- References -- 9 An overview of seismic design and sustainability of high-rise buildings -- 9.1 Introduction to seismology -- 9.1.1 Seismic magnitude -- 9.1.2 Seismic intensity -- 9.1.3 Ground movement during earthquakes -- 9.2 Response spectrum of building structures -- 9.2.1 Seismic response of single-degree freedom (SDF) structure -- 9.2.2 Seismic action -- 9.2.3 Seismic response spectrum -- 9.3 Seismic action and response of high-rise buildings -- 9.3.1 Seismic action of vibration mode of high-rise buildings -- 9.3.2 Seismic response of high-rise buildings without torsion -- 9.3.3 Seismic response of high-rise buildings with torsion -- 9.4 Seismic resistance of high-rise buildings -- 9.4.1 Strength requirement -- 9.4.2 Deformation requirement -- 9.5 Basic concepts for seismic resistance of high-rise buildings -- 9.5.1 Selection of suitable site for buildings -- 9.5.2 Regular building forms -- 9.5.3 Reasonable seismic resistance system -- 9.5.4 Strong slab for floors -- 9.6 Technologies for mitigating seismic effects on high-rise buildings. | |
| 9.6.1 Seismic isolation principle and technology -- 9.6.2 Energy dissipation principle and technology -- 9.6.3 Tuned mass damper (TMD) principle and technology -- 9.7 Conclusion -- Symbols -- References -- 10 Sustainable construction of wood high-rise buildings and seismic considerations -- 10.1 Introduction -- 10.2 Scope and objectives -- 10.3 Sustainability -- 10.4 Re-emergence of tall wood buildings -- 10.5 Tall wood initiatives in North America -- 10.5.1 Research and development of wood products and systems -- 10.6 Cross-laminated timber (CLT) -- 10.7 Structural systems for tall wood and composite buildings -- 10.8 Moisture content and effects on material properties -- 10.9 Case study I: Wood Innovation Design Centre -- 10.10 Tall wood and composite buildings in seismic regions -- 10.11 Connections and ductility -- 10.12 Case study II: UBC Brock Commons -- 10.13 Innovative solutions for wood structures -- 10.13.1 Self-centering and low-damage structures -- 10.13.2 Application of self-centering and low-damage technology -- 10.14 Conclusion -- Acknowledgments -- References -- 11 Innovative mass-damping approaches for sustainable seismic design of tall buildings -- 11.1 Introduction -- 11.2 Literature review -- 11.2.1 Mega-substructure-control system (MSCS) -- 11.2.2 Intermediate isolation system (IIS) -- 11.3 Modeling, design parameters, analysis types -- 11.3.1 Baseline (FB) models of uncontrolled configurations -- 11.3.2 MSCS models and design parameters -- 11.3.3 IIS models and design parameters -- 11.3.4 Reduced-order models (2DOF and 3DOF) -- 11.3.5 Dynamic problem formulation and analysis methods -- 11.4 MSCS configurations: analyses -- 11.4.1 Classical modal analysis -- 11.4.2 Complex modal analysis -- 11.4.3 Response spectrum analysis (RSA) -- 11.4.4 Time history analyses. | |
| 11.4.5 Effect of the distribution of moving secondary substructures. | |
| Sommario/riassunto: | The rapid increase in globalization, human population, land prices and climate change are forcing cities to build upward. From architecture to engineering and city planning, this comprehensive reference covers the state-of-the-art of advanced research, innovations and future perspectives towards sustainable high-rise buildings. |
| Altri titoli varianti: | Sustainable High-Rise Buildings Design, technology, and innovation |
| Sustainable High Rise Buildings : design Technology and innovation | |
| Titolo autorizzato: | Sustainable High-Rise Buildings |
| ISBN: | 9781523153329 |
| 1523153326 | |
| 9781839532818 | |
| 1839532815 | |
| Formato: | Materiale a stampa  |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione: | Inglese |
| Record Nr.: | 9911004836203321 |
| Lo trovi qui: | Univ. Federico II |
| Opac: | Controlla la disponibilità qui |
Serie:
Built Environment