Key Features: Clear language is used which aids in explaining technical terminology and concepts. Fully worked examples are provided within each section. Self-evaluation questions with answers are included in each section for immediate practice and feedback. The answers to the self-evaluation questions appear at the end of each chapter. The process of constructing a house is used as a golden thread throughout the book, acting as an example, and demonstrating the practical application of civil engineering materials. A methodology is used that is suitable for both contact and distance education.

Solar cooling systems can be a cost-effective and environmentally attractive air-conditioning solution. The design of such systems, however, is complex. Research carried out under the aegis of the International Energy Agency's Solar Heating and Cooling Program has shown that there is a range of seemingly subtle design decisions that can impact significantly on the performance of solar cooling systems. In order to reduce the risk of errors in the design process, this guide provides detailed and very specific engineering design information. It focuses on case study examples of installed plants that have been monitored and evaluated over the last decade. For three successful plants the design process is described in detail and the rationale for each key design decision is explained. Numerical constraints are suggested for the sizing / selection parameters of key equipment items. Moreover, the application conditions under which the system selection is appropriate are discussed. By following The Guide for any of the three specific solar cooling systems, the designer can expect to reliably achieve a robust, energy-saving solution. This book is intended as a companion to the IEA Solar Cooling Handbook which provides a general overview of the various technologies as well as comprehensive advice to enable engineers to design their own solar cooling system from first principles.

Bad experiences with construction quality, the energy crises of 1973 and 1979, complaints about "sick buildings", thermal, acoustical, visual and olfactory discomfort, the need for good air quality, the move towards more sustainability - all these have accelerated the development of a field that, for a long time, was hardly more than an academic exercise: building physics (in English speaking countries sometimes referred to as building science). The discipline embraces domains such as heat and mass transfer, building acoustics, lighting, indoor environmental quality and energy efficiency. In some countries, fire safety is also included. Through the application of physical knowledge and its combination with information coming from other disciplines, the field helps to understand the physical phenomena governing building parts, building envelope, whole buildings and built environment performance, although for the last the wording "urban physics" is used. Today, building physics has become a key player on the road to a performance based building design. The book deals with the description, analysis and modeling of heat, air and moisture transport in building assemblies and whole buildings with main emphasis on the building engineering applications, including examples. The physical transport processes determine the performance of the building envelope and may influence the serviceability of the structure and the whole building. Compared to the second edition, in this third edition the text has partially been revised and extended.

Offering critical insights to the state-of-the-art in Building Information Modeling (BIM) research and development, this book outlines the prospects and challenges for the field in this era of digital revolution. Analysing the contributions of BIM across the construction industry, it provides a comprehensive survey of global BIM practices. Accessible and thorough, the chapters explore the theory behind and facilitators of BIM, covering knowledge management around BIM, the development of ontologies and language in the area, holistic implementations, and BIM ecosystems. The book further discusses the technological developments of BIM, including scan-to-BIM, 3D digital reconstruction and AI and robotics techniques. Critical analysis of BIM-enabled construction and engineering management innovations are also examined, highlighting prospects and challenges in the area. This will be a critical read for engineering, construction management and architecture students looking for a comprehensive study of BIM. It will also be beneficial to practitioners working in the Architecture, Engineering, Construction, Owner & Operation (AECOO) industry wanting a better understanding of the benefits and future developments of BIM.

For courses in architecture and civil engineering. Reinforced Concrete: Mechanics and Design uses the theory of reinforced concrete design to teach students the basic scientific and artistic principles of civil engineering. The text takes a topic often introduced at the advanced level and makes it accessible to all audiences by building a foundation with core engineering concepts. The 7th Edition is up-to-date with the latest Building Code for Structural Concrete, giving students access to accurate information that can be applied outside of the classroom. Students are able to apply complicated engineering concepts to real world scenarios with in-text examples and practice problems in each chapter. With explanatory features throughout, the 7th Edition makes the reinforced concrete design a theory all engineers can learn from.

Building energy design is currently going through a period of major changes. One key factor of this is the adoption of net-zero energy as a long term goal for new buildings in most developed countries. To achieve this goal a lot of research is needed to accumulate knowledge and to utilize it in practical applications. In this book, accomplished international experts present advanced modeling techniques as well as in-depth case studies in order to aid designers in optimally using simulation tools for net-zero energy building design. The strategies and technologies discussed in this book are, however, also applicable for the design of energy-plus buildings. This book was facilitated by International Energy Agency's Solar Heating and Cooling (SHC) Programs and the Energy in Buildings and Communities (EBC) Programs through the joint SHC Task 40/EBC Annex 52: Towards Net Zero Energy Solar Buildings R&D collaboration. After presenting the fundamental concepts, design strategies, and technologies required to achieve net-zero energy in buildings, the book discusses different design processes and tools to support the design of net-zero energy buildings (NZEBs). A substantial chapter reports on four diverse NZEBs that have been operating for at least two years. These case studies are extremely high quality because they all have high resolution measured data and the authors were intimately involved in all of them from conception to operating. By comparing the projections made using the respective design tools with the actual performance data, successful (and unsuccessful) design techniques and processes, design and simulation tools, and technologies are identified. Written by both academics and practitioners (building designers) and by North Americans as well as Europeans, this book provides a very broad perspective. It includes a detailed description of design processes and a list of appropriate tools for each design phase, plus methods for parametric analysis and mathematical optimization. It is a guideline for building designers that draws from both the profound theoretical background and the vast practical experience of the authors.

Edward Jenner is perhaps the world's most famous doctor. He developed a vaccination for smallpox beginning in 1796, long before the world knew about bacteria and viruses. He has been described as `the man who saved more lives than anyone else'. He bought The Chantry at Berkeley in 1785 and modified it to make a home fit for his beloved wife, Catherine. This book is the result of a three-year investigation that set out to discover the house that Jenner prepared for Catherine. It traces the origin of the house, which was built in 1707, and the many changes throughout the next 300 years. It turns out that the site has a history going back to Anglo-Saxon times. Edward Jenner lived there for only thirty-six years, but the house has been much changed since. The investigation set out to define the house that Edward Jenner lived in, separating it from the original and many changes afterwards. The book includes a great deal of information and stories about the people involved, including Edward Jenner and his family and estate. It also includes the inventory of Jenner's goods in 1823 and profiles of the internal plasterwork, which may be of interest to restorers and historians.

Just like building physics, performance based building design was hardly an issue before the energy crises of the 1970ies. With the need to upgrade energy efficiency, the interest in overall building performance grew. The term "performance" encompasses all building-related physical properties and qualities that are predictable during the design stage and controllable during and after construction. The term "predictable" demands calculation tools and physical models that allow evaluating a design, whereas "controllable" presumes the existence of measuring methods available on site. The basis for a system of performance arrays are the functional demands, the needs for accessibility, safety, well-being, durability, energy efficiency and sustainability and the requirements imposed by the usage of a building. In continuation of Vol. 1 this second volume discusses light-weight construction with wooden and metal elements, roofing systems, facades, and ends with finishes and the overall risk analysis. Most chapters build on a same scheme: overview, overall performance evaluation, design and construction. The work is absolutely recommended to undergraduates and graduates in architectural and building engineering, though also building engineers, who want to refresh their knowledge, may benefit. The level of discussion assumes the reader has a sound knowledge of building physics, along with a background in structural engineering, building materials and building construction. Where and when needed, input and literature from over the world was used, reason why each chapter ends listing references and literature.

This new, revised edition of Approved Document B incorporates the June 2022 amendment booklet which takes effect on 1st December 2022. Approved Document B of the Building Regulations covers fire safety matters within and around buildings. Published in two volumes, this volume - Volume 1 - deals solely with dwellings, including blocks of flats, while Volume 2 deals with all other types of building cover by the Building Regulations. The aim of each volume is to set out the guidelines that need to be followed in order to prevent the spread of fire over linings, such as walls and ceilings. Each volume also states what materials can be used and what British Standards each should conform to, to ensure that they provide the required level of protection. Main changes made by the 2022 amendments The changes focus on the following fire safety provisions: a. Ban of combustible materials in and on the external walls of buildings: Consequential amendments following the laying of the Building (Amendment) (England) Regulations 2022. Updated provisions in Section 10 for residential buildings (purpose groups 1 and 2) with a storey 11m or more in height. b. Secure information boxes: A new recommendation for secure information boxes in blocks of flats with storeys over 11m. c. Evacuation alert systems: A new recommendation for evacuation alert systems in blocks of flats with storeys over 18m.

Just like building physics, performance based building design was hardly an issue before the energy crises of the 1970s. With the need to upgrade energy efficiency, the interest in overall building performance grew. The term "performance" encompasses all building-related physical properties and qualities that are predictable during the design stage and controllable during and after construction. The term "predictable" demands calculation tools and physical models that allow evaluating a design, whereas "controllable" presumes the existence of measuring methods available on site. The basis for a system of performance arrays are the functional demands, the needs for accessibility, safety, well-being, durability, energy efficiency and sustainability and the requirements imposed by the usage of a building. As the first of two volumes, this book applies the performance rationale, advanced in applied building physics, to the design and construction of buildings. After an overview of materials for thermal insulation, water proofing, air tightening and vapour tightening and a discussion on joints, building construction is analysed, starting with the excavations. Then foundations, below and on grade constructions, typical load bearing systems and floors pass the review to end with massive outer walls insulated at the inside and the outside and cavity walls. Most chapters build on a same scheme: overview, overall performance evaluation, design and construction. The book is absolutely recommended to undergraduates and graduates in architectural and building engineering, though also building engineers, who want to refresh their knowledge, may benefit. The level of discussion assumes the reader has a sound knowledge of building physics, along with a background in structural engineering, building materials and building construction. Where and when needed, input and literature from over the world was used, reason why each chapter ends listing references and literature.

This Approved Document provides guidance on how to comply with Part F to Schedule 1 to the Building Regulations covering ventilation and applies to dwellings only, and takes effect on 15 June 2022. It does not apply to work subject to a building notice, full plans application or initial notice submitted before that date, provided the work is started on site before 15 June 2023. ADF1: Dwellings (2021 edition) contains the following sections: Ventilation provision Minimising the ingress of external pollutants Work on existing dwellings Commissioning and providing information Key terms Performance-based ventilation Completion checklist and commissioning sheet Checklist for ventilation provision in existing dwellings The guidance in this Approved Document only relates to England and applies to dwellings only. In a mixed-use building, Approved Document F, Volume 2: Buildings other than dwellings should be consulted for building work in parts of the building that are not dwellings.

This Approved Document provides guidance on how to comply with Part L to Schedule 1 of the Building Regulations covering the conservation of fuel and power and the associated energy efficiency requirements for dwellings, and takes effect on 15 June 2022. It does not apply to work subject to a building notice, full plans application or initial notice submitted before that date, provided the work is started on site before 15 June 2023. ADL1: Conservation of fuel and power - Dwellings (2021 edition) contains the following sections: Calculating the target primary energy rate, target emission rate and target fabric energy efficiency rate Calculating the dwelling primary energy rate, dwelling emission rate and dwelling fabric energy efficiency rate Consideration of high efficiency alternative systems Limiting heat gains and losses Minimum building services efficiencies and controls - general guidance System specific guidance Air permeability and pressure testing Commissioning Providing information New elements in existing dwellings, including extensions Work to elements in existing dwellings Consequential improvements Key terms Reporting evidence of compliance Work to thermal elements The guidance in this Approved Document only relates to England and applies to dwellings only. In a mixed-use building, Approved Document L, Volume 2: Buildings other than dwellings should be consulted for building work in parts of the building that are not dwellings.

This Approved Document provides guidance on how to comply with Part L to Schedule 1 of the Building Regulations and the associated energy efficiency requirements for buildings other than dwellings, and takes effect on 15 June 2022. It does not apply to work subject to a building notice, full plans application or initial notice submitted before that date, provided the work is started on site before 15 June 2023. ADL2: Conservation of fuel and power - Buildings other than dwellings (2021 edition) contains the following sections: Calculating the target primary energy rate and target emission rate Calculating the building primary energy rate and dwelling emission rate Consideration of high efficiency alternative systems Limiting heat gains and losses Minimum building services efficiencies and controls - general guidance System specific guidance Air permeability and pressure testing Commissioning Providing information New elements in existing buildings, including extensions Work to elements in existing buildings Consequential improvements Key terms Lighting Energy Numeric Indicator (LENI) Reporting evidence of compliance Measures for consequential improvements Hierarchy for establishing seasonal efficiencies of existing boilers The guidance in this Approved Document only relates to England and applies to dwellings other than dwellings only. For guidance relating to dwellings, use Approved Document L, Volume 1: Dwellings.

This Approved Document provides guidance on how to comply with Part O to Schedule 1 to the Building Regulations covering overheating mitigation requirements and applies to new residential buildings only. It takes effect on 15 June 2022 but does not apply to work subject to a building notice, full plans application or initial notice submitted before that date, provided the work is started on site before 15 June 2023. ADO: Overheating contains the following sections: Simplified method Dynamic thermal analysis Ensuring the overheating mitigation strategy is usable Providing information Key terms Compliance checklist Areas at a high risk of buildings overheating The guidance in this Approved Document only relates to England.

All new homes and buildings in England will be required by law to install electric vehicle charging points from June 2022. New-build supermarkets, workplaces and buildings undergoing major renovations will also come under the new law. This Approved Document provides guidance on how to comply with Part S to Schedule 1 to the Building Regulations covering electric vehicle charging infrastructure requirements and takes effect on 15 June 2022. It does not apply to work subject to a building notice, full plans application or initial notice submitted before that date, provided the work is started on site before 15 June 2023. ADS: Infrastructure for the charging of electric vehicles covers: New residential buildings New non-residential buildings Buildings undergoing material change of use Residential buildings undergoing major renovation Non-residential buildings undergoing major renovation Mixed-use buildings undergoing relevant building work The guidance in this Approved Document only relates to England.