Wind Effects on Buildings and Design of Wind-Sensitive Structures
The articles in this book, written by seven internationally known experts, present the fundamentals and practical applications of comtemporary wind engineering dealing with wind-building interaction complex problems from the perspective of a structural designer. Both experimental and computational approaches and their relative merits are presented and analyzed. The book presents state-of-the-art material in a rapidly progressing area that cannot be found in any other of the limited number of books in this area. Junior architects and engineers will learn the treatment of wind engineering , an area not traditionally taught at underground university programs. Junior structural designers will be informed about the progress made on experimental and computational wind engineering design of complex structures.
Soft Ground Tunnel Design
Teaches the principles of tunnel and underground space design in soft ground. ‘Soft ground’ refers to soil, in contrast to rock. The book focuses on stability, prediction of ground movements, and structural design of the lining. It shows that the choice of excavation and support methods depends on ground stability, limitation of damage to the existing built environment, and health, safety and environmental considerations. Readers will be able to: understand the basis for choosing an underground construction method and/or ground improvement method / calculate heading stability / predict ground movements / understand the complex soil-structure interaction around an advancing tunnel / design tunnel linings in soft ground using a variety of methods / predict the effects of construction on the built environment and assess potential damage
Probabilistic Methods in Geotechnical Engineering
Soils and rocks are among the most variable of all engineering materials, and as such are highly amenable to a probabilistic treatment. The application of statistical and probabilistic concepts to geotechnical analysis is a rapidly growing area of interest for both academics and practitioners. The book is therefore aimed at students, researchers, and practitioners of geotechnical engineering who wish to keep abreast of developments in this evolving field of study.
Practical design of timber structures to Eurocode 5
Provides a comprehensive guide to the design of timber structures according to the latest European and UK standards. Practical Design of Timber Structures to Eurocode 5 begins with a description of timber, considering its strength, stiffness, moisture behaviour, rheology and durability, before going on to describe the production and relevant properties of materials used for timber structures.
Finite element analysis and design of steel and steel–concrete composite bridges
The book’s eight chapters begin with an overview of the various forms of modern steel and steel-concrete composite bridges, current design codes (American, British, and Eurocodes), nonlinear material behavior of the bridge components, and applied loads and stability of steel and steel-concrete composite bridges. This is followed by self-contained chapters concerning design examples of steel and steel-concrete composite bridge components as well as finite element modeling of the bridges and their components. The final chapter focuses on finite element analysis and the design of composite highway bridges with profiled steel sheeting.
Earth Structures : In Transport, Water and Environmental Engineering
This book describes the principles of working with soil as a construction material, including two basic ways of treating it: geosynthetics and stabilization. The book discusses the design logic and ways to control Earth Structures, which differ significantly from other construction materials. Building with Earth involves greater uncertainty and risk, which means that there is a need for better design detailing and improvement in the quality of financial calculations. The general part of the book gives a detailed description of the principles of limit states according to Eurocode 7, after which geotechnical design is also described. Subsequent chapters concentrate on earth structures for transport, water, and environmental projects. The chapter on Earth Structures in transport engineering presents detailed coverage of limit states of stability and deformation. Earth Structures in water engineering prioritizes the limit state of internal erosion. Earth Structures in environmental engineering describes new designs, in which part of the structure is created from non-standard materials which are usually susceptible to internal collapse, double porosity, unsaturation, etc. It also focuses on protecting the surrounding environment from contamination.
Designers' guide to Eurocode 1 : Actions on buildings : EN1991-1-1 and -1-3 TO -1-7
Provides comprehensive guidance in the form of design aids, indications for the most convenient design procedures and worked examples. The books also include background information to aid the designer in understanding the reasoning behind and the objectives of the codes. All of the individual guides work in conjunction with the Designers' Guide to EN 1990 Eurocode: Basis of Structural Design.
Designers' guide to Eurocode 1 : Actions on Bridges : EN 1991-2, EN 1991-1-1, -1-3 TO -1-7 and EN 1990 Annex A2
Provides comprehensive guidance in the form of design aids, indications for the most convenient design procedures and worked examples. The books also include background information to aid the designer in understanding the reasoning behind and the objectives of the codes. All of the individual guides work in conjunction with the Designers' Guide to EN 1990 Eurocode: Basis of Structural Design. The parts of Eurocode 1 covered by this guide, EN 1991-1 and EN 1991-2, address the general actions and traffic loads on civil engineering structures. This Designers' Guide looks specifically at these actions as they apply to bridges, including full explanation, commentary, examples, and direction to the National Annex documents on each of the following parts and sub-parts of the code. EN1990 Annex 2: Basis of structural design.
Designers' guide to EN1991-1-2, EN1992-1-2, EN1993-1-2 and EN1994-1-2 : Handbook for the fire design of steel, composite and concrete structures to the Eurocodes
The nature of the loading must first be understood before applying the structural engineering principles set out in the Eurocodes. For this reason this book is meant as a guide to four separate documents, EN1991 Part 1.2, EN1992 Part 1.2, EN1993 Part 1.2 and EN1994 Part 1.2 with reference where appropriate to the Eurocode covering the basis of design, EC06.
Designers' guide to EN 1998-1 and 1998-5. Eurocode 8 : Design provisions for earthquake resistant structures
Provides comprehensive guidance in the form of design aids, indications for the most convenient design procedures and worked examples. The books also include background information to aid the designer in understanding the reasoning behind and the objectives of the codes. All of the individual guides work in conjunction with the Designers' Guide to EN1990 Eurocode: Basis of Structural Design.
Designers' guide to EN 1997-1 Eurocode 7 : Geotechnical Design – General Rules
Designers' Guide to EN 1997-1 presents a detailed guide to the new Geotechnical Design Eurocode.As such it gives an invaluable insight into a code that, for the first time, provides a comprehensive design philosophy that is not only applicable to all forms of geotechnical problems but also shares a common philosophy with the design methodology for structures of all the commonly encountered construction materials.
Designers' guide to EN 1994-2 Eurocode 4 : Design of steel and composite structures ; Part 2 : General rules and rules for bridges
It is an authoritative guide to the technical background and practical aspects of this European code of practice that will supersede corresponding national codes in the countries that are members of the European Standardisation Organisation - CEN (Comite Europeen de Normalisation). This book provides guidance on the interpretation and use of EN 1994-2 and presents worked examples. It deals with the issues that are encountered in typical steel and concrete composite bridge designs, and explains the relationships between EN 1994-1-1, EN 1994-2 and the other Eurocodes.
Designers' guide to EN 1993-2 Eurocode 3: Design of Steel Structures: Part 2: Steel Bridges
Describes the principles and requirements for safety, serviceability and durability of concrete bridges. This Designers' Guide provides the user with guidance on the interpretation and use of EN 1993-2 and also the relevant provisions in EN 1993-1-1, EN 1993-1-5, EN 1993-1-8, EN 1993-1-9, EN 1993-1-10 and EN 1993-1-11. Worked examples are provided to illustrate the use of the rules. It also explains the relationship with other Eurocode parts to which it refers (ENs 1990, 1991).
Designers' guide to EN 1993-1-1 Eurocode 3 : Design of Steel Structures: General Rules and Rules for Buildings
After some 25 years in preparation, the key parts of EN 1993 Eurocode 3: Design of steel structures have now been finalised.? Designers Guide to EN 1993-1-1 covers many forms of steel construction and provides the most comprehensive and up-to-date set of design guidance currently available.
Designers' guide to EN 1992-2 Eurocode 2 : Design of concrete structures : Part 2: Concrete bridges
Describes the principles and requirements for safety, serviceability and durability of concrete bridges. It provides the user with guidance on the interpretation and use of EN 1992-2 and the relevant provisions of the general rules ofEN 1992-1-1. Worked examples are provided to illustrate the use of the rules. It also explains the relationship with the other Eurocode parts to which if refers (ENs 1990, 1991).
Designers' guide to EN 1991-1-4 Eurocode 1 : Actions on structures, general actions part 1–4. Wind actions
EN1991-1-4, Eurocode 1: Actions on structures -General actions - Part 1-4: Wind actions, is the head code for wind actions on structures and describes the principles and requirements for calculating design wind loads on structures. It complies with the requirements of Eurocode EN1990, Eurocode: Basis of Structural Design, and provides the wind actions necessary to implement the structural design Eurocodes 2 to 9.
Designers' guide to EN 1990 Eurocode : Basis of structural design
EN 1990: Basis of Structural Design is considered the primary document in the Eurocode suite and establishes for the structural Eurocodes the principles and requirements for safety and serviceability of structures. More importantly, EN 1990 must be applied whenever the Eurocodes 1 to 9 are used.
Design of structural elements : Concrete, steelwork, masonry and timber designs to Eurocodes
Topics include the philosophy of design, sustainable development, basic structural concepts, and material properties. After an overview of structural design, the book contains self-contained chapters with numerous diagrams and worked examples on design in reinforced concrete, structural steelwork and steel/concrete composites, masonry and timber based on EN 1990-1997. Elements considered cover reinforced concrete and composite floors, isolated foundation, cantilever retaining wall, load-bearing and panel walls, stud wall and connections.
Design of Reinforced Concrete Sections Under Bending and Axial Forces : Tables and Charts According to EUROCODE 2
Contains auxiliary calculation tools to facilitate the safety assessment of reinforced concrete sections. Essential parameters in the design to the ultimate limit state of resistance such as the percentage of reinforcement and the position of the neutral axis in concrete cross-sections, as well as the control of the maximum stresses in service limit states are provided by these tools.
Design of Reinforced Concrete Buildings for Seismic Performance : Practical Deterministic and Probabilistic Approaches
Presents an elegant, simple and theoretically coherent design framework. Required strength is determined on the basis of an estimated yield displacement and desired limits of system ductility and drift demands. A simple deterministic approach is presented along with its elaboration into a probabilistic treatment that allows for design to limit annual probabilities of failure. The design method allows the seismic force resisting system to be designed on the basis of elastic analysis results, while nonlinear analysis is used for performance verification. Detailing requirements of ACI 318 and Eurocode 8 are presented. Students will benefit from the coverage of seismology, structural dynamics, reinforced concrete, and capacity design approaches, which allows the book to be used as a foundation text in earthquake engineering.



















