Energy Efficient Building Design

✍ Scribed by Ana-Maria Dabija (editor)

Publisher: Springer
Year: 2020
Tongue: English
Leaves: 281
Category: Library

No coin nor oath required. For personal study only.

✦ Synopsis

This book is the result of recent research that deals with the built environment and innovative materials, carried out by specialists working in universities and centers of research in different professional fields ─ architecture, engineering, physics ─ and in an area that that spans from the Mediterranean Sea to the Persian Gulf, and from South Eastern Europe to the Middle East. This book takes the necessity of re-shaping the concept of building design in order to transform buildings from large scale energy consumers to energy savers and producers into consideration. The book is organized in two parts: theory and case studies. For the theoretical part, we chose from the wide range of sources that provide energy efficient materials and systems the two that seem to be endless: the sun and vegetation. Their use in building products represents a tool for specialists in the architectural design concept. The case-studies presented analyze different architectural programs, in different climates, from new buildings to rehabilitation approaches and from residential architecture to hospitals and sports arenas; each case emphasizes the interdisciplinarity of the building design activity in order to help readers gain a better understanding of the complex approach needed for energy efficient building design

✦ Table of Contents

Preface
Contents
Part I: Building with the Sun – An Everlasting Energy Source
Chapter 1: A Review of the Significance and Challenges of Building Integrated Photovoltaics
1.1 Introduction
1.1.1 Justification
1.2 Background
1.3 The Importance of BIPV
1.3.1 BIPV as an Energy Source: ‘The Energy Dimension’
1.3.2 BIPV as a Building Component: ‘The Building Dimension’
1.4 BIPV Development and Challenges
1.4.1 BIPV Challenges
1.5 Further Research
1.6 Conclusion
References
Chapter 2: Design Opportunities and Building Integration of PV systems
2.1 Introduction
2.2 Methodology
2.2.1 Adaptation of the Solar Radiation
2.2.2 Temperature Adaptation
2.2.3 Model of the PV Efficiency
2.2.4 Studied Orientations
2.3 Computation Study
2.4 Experimental Study
2.5 Conclusions
References
Chapter 3: Optimization of Performances and Reliability for Building-Integrated Photovoltaic (BIPV) Systems
3.1 Introduction
3.2 Standards Used for BIPV Systems
3.3 State of the Art for BIPV Systems
3.4 Modeling, Numerical Simulation, and Optimization of BIPV Systems
3.4.1 Modeling and Simulation Techniques for BIPV Systems
3.4.1.1 MPPT Techniques
3.4.1.2 Fuzzy Logic Controller (FLC)
3.4.2 Implementation of the FLC-Based MPPT Algorithm for Numerical Modeling of BIPV Systems
3.5 Case Study: Results Obtained by Optimizing a BIPV System
3.6 Reliability Analysis of the Studied BIPV System: Obtained Results
3.7 Conclusion
References
Chapter 4: Inorganic, Coloured Thin Films for Solar Thermal Energy Convertors in Sustainable Buildings
4.1 Introduction
4.2 Driving Forces in Implementing Solar Thermal Systems
4.2.1 Social System in Interaction with Environment
4.2.2 Environmental Perturbation as Consequence of Energy Consumption
4.3 Coloured Solar Thermal Flat Plate Collectors
4.3.1 Flat Plate Solar Thermal Collectors
4.3.2 Materials for the Absorber Layer
4.3.3 Coloured Materials for Absorber Coatings in FPSTC
4.4 Conclusions
References
Chapter 5: Capitalizing on Solar Energy in Romania and Improving the Thermal Comfort of Buildings with Solar Air Collectors
5.1 Introduction
5.2 Solar Irradiation
5.2.1 Climate of Selected Localities
5.2.2 Solar Global Irradiation: Average Monthly Values
5.2.3 Sunshine Duration
5.3 Experimental Measurement of Solar Irradiation in Bucharest During 2017–2018
5.4 Solar Air Collectors to Improve the Thermal Buildings’ Comfort
5.4.1 Classification Based on Technologies
5.4.2 Performances of Thermo-Solar Collectors
5.4.3 Solar Air Collectors Integrated in the Building Architecture
5.5 Conclusion
References
Part II: Building with the Nature
Chapter 6: Parallel (Hi)Stories: A Subjective Approach to Energy-Efficient Design
6.1 Introduction
6.2 The Perennial of the Vernacular
6.3 Bioclimatic: A Heritage of the Vernacular
6.4 Old or New Facades
6.4.1 Trombe Walls
6.4.2 Solar Facades
6.4.3 Living Facades
6.4.4 Double-Skin Facades
6.5 Hanging Gardens of Semiramis or Eco-Roofs
6.6 Conclusions
References
Chapter 7: Traditional Semi-Buried House
7.1 Introduction
7.2 The “Bordei”
7.2.1 Problems of in the Traditional “Bordei” House Concept
7.2.1.1 Moisture
7.2.1.2 Floods
7.2.1.3 Difficult Access
7.2.1.4 Insufficient Natural Lighting
7.2.1.5 Poor Ventilation of the Interior Space
7.2.1.6 Heat Losses
7.2.2 “Bordei” House Advantages
7.2.2.1 Organic Building
7.2.2.2 It Was Built with Materials from the Area: Wood, Earth, and Clay
7.2.2.3 Low-Energy Consumption During the Construction Period
7.2.2.4 Orientation Toward the Cardinal Points
7.2.2.5 The Floor Below Ground Level
7.2.2.6 Thermal Insulation
7.2.2.7 The High Thermal Mass of the Earth Elements and the Existence of an Earth Stove
7.2.2.8 Capacity to Regulate Humidity
7.3 Proposals for Modernizing a “Bordei” House
7.3.1 Moisture Reduction
7.3.2 Avoiding Flood Zones
7.3.3 Making the Entrance Easy to Use
7.3.4 Natural Light According to the Norms
7.3.5 Ensuring Sufficient Ventilation
7.3.6 Correct Thermal Insulation of the Outer Shell
7.4 Conclusions
References
Chapter 8: Using Agricultural By-products for Creating Innovative Technologies and Materials
8.1 Introduction: Energy and Recycling
8.2 Bio-Based Products and Wastes
8.3 LCA Comparison Between Two Products for Vertical Closures
8.4 Conclusion
References
Part III: Case Studies
Chapter 9: Les conditions de la nature sont retrouvèe: The Tower of Shadow in Chandigarh and Other Le Corbusier’s Masterpieces
9.1 Introduction
9.2 Results and Discussions
9.2.1 The Tower of Shadows, Chandigarh
9.2.2 Palais de l’Association des Filateurs
9.2.3 Two European Experiences: La Tourette Convent and the Unité d’Habitation
9.3 Conclusions
References
Chapter 10: Sustainability and Energy Efficiency Design in Hospital Buildings
10.1 Introduction
10.2 Defining Sustainability and Energy Efficiency in Modern Healthcare Buildings
10.3 The WHO Calls for More “Green Hospitals” and the Quest for the ZERO Waste Hospital
10.4 Hospitals in the Future and Necessary Design Needs/Goals
References
Chapter 11: Football Stadium: An Energy-Efficient Building and a Source of Renewable Energy for the Community
11.1 Introduction
11.2 The Sport and the Stadium
11.3 Game-Related Legislation and European Norms
11.3.1 Reports and Game-Related Legislation: Impact Upon Design Norms
11.3.2 European Directives Concerning Sustainability and Sustainability Standards
11.4 The Sustainability of Football Stadiums
11.4.1 Economic and Environmental Sustainability
11.4.2 Social Sustainability
11.5 The Outcomes of Stadiums as Multifunctional Buildings
11.6 Conclusions
References
Chapter 12: Passive Design Strategies in Pursuit of Architectural Identity: The New ACT Student Center
12.1 Introduction
12.2 Brief - Site - Further Background Research
12.2.1 The Brief
12.2.2 The Site
12.2.3 Further Background Research
12.3 Environmental Concepts and Principles
12.3.1 Building Energy Performance Goals
12.3.2 Climatic and Microclimatic Conditions
12.4 Environmental Architectural Design
12.5 Environmental Design Simulation
12.6 Discussion
References
Chapter 13: Towards a Sustainable Refurbishment of the Hellenic Residential Building Stock
13.1 Introduction
13.2 Hellenic Residential Buildings
13.2.1 Building Stock Model (BSM)
13.2.2 Calculations
13.2.2.1 Adaptation Factors from EPCs
13.2.2.2 Adaptation Factors from Field Surveys
13.3 Modelling the Hellenic Building Stock: A Realistic Outlook
13.3.1 Validation
13.3.2 Renovation Scenarios Towards 2030
13.4 Conclusions
References
Chapter 14: Design Strategies for Green/Energy-Efficient Building Design: An Apartment Building in the Gaziantep Project
14.1 Introduction
14.2 Energy-Efficient Building Design Decisions
14.2.1 Passive Design Principles and Strategies
14.2.1.1 Natural Ventilation and Wind Control Principles and Strategies
14.2.1.2 Sun Control and Natural Daylighting
14.2.1.3 Green Roof
14.2.1.4 Envelope Design and Insulation
14.2.2 Active Solar Systems
14.2.3 Resource Conservation and Local Material Use
References
Chapter 15: A Sustainable Approach Towards Energy Savings in the Cities of Romania, Bucharest: A Case Study
15.1 A Brief History of the Residential Collective Apartments in Bucharest
15.2 Energy Efficiency in Buildings
15.3 Green Energy Trends
15.4 Greening the City
15.5 Conclusions
References
Chapter 16: The Heat Island as a Result and Cause of Environmental and Social Degradation: Two Different Settlements in the Town of Afragola of the Metropolitan City of Naples
16.1 Introduction
16.2 Heat Island in the Batch of Buildings in Line
16.2.1 Application and Comparison Between the Two Methods
16.3 Microclimate and Usability of the Garden Courts
16.4 Conclusions
References
Chapter 17: Settlement Scale Analysis Approach to Reach Nearly Zero Energy Communities
17.1 Introduction
17.2 Methodology
17.3 Results
17.4 Conclusions
References
Index

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