Flood control in urban areas can be feasibly and cost-effectively enhanced by implementing flood proofing approaches to risk reduction in the context of environmental and land-use planning and management. Indeed, flood proofing makes it possible to improve, integrate and in some cases even replace traditional measures for flood control, reducing the vulnerability and increasing the resilience of buildings and infrastructures.

This book begins by reviewing the physics of stability and instability of both human beings and buildings under flood conditions, together with criteria and models (both conventional and innovative) for assessing flood strains. In turn, it presents a range of flood proofing concepts and techniques, together with a complete and updated classification of related methods and devices. This provides a user-friendly tool to help identify appropriate solutions to real-world problems for each specific risk scenario.

In particular, the book focuses on temporary flood proofing techniques, given their ability to deliver effective performance at low costs. Lastly, it features an overview of norms, guidelines and laboratory recommendations that are currently being adopted in various countries with regard to flood proofing devices and testing procedures. The purpose of this book is essentially to encourage authorities, stakeholders, technicians and end users to successfully develop flood proofing solutions that can reduce flood risk in a pragmatic manner. In addition, the authors hope to inspire researchers, manufacturers and designers (engineers, architects, urban planners and urban managers) to pursue further advances in this key sector of public and private safety in urban areas.

Autorentext

Environmental and Land Planning Engineer and Ph.D., Daniele F. Bignami (National Scientific Qualification as Associate Professor, sector Urban and landscape planning and design) is at present in charge of the course Land planning for risk management of the MS of Architecture of the built environment at Politecnico di Milano, where he carried out teaching since 2006 in the field of Disaster Risk Reduction. Meanwhile he collaborated with the Italian Government - Civil Protection Department, and also with the Institute for an Industrial Safety Culture of Toulouse (France). Author of 3 books (and editor of 4 more) and author of more than 40 papers, mainly in the field of disaster management, built environment and urban issues, in 2005 he was hired by Politecnico of Milan Foundation as Research Project Manager, where he currently works, having gained experience from more than 40 projects achieved.

Renzo Rosso is a professor of Hydrology and Water Engineering at Politecnico di Milano, Italy since 1986. He received the Borland Award for Hydrology in 2005, and the Henry Darcy Medal by the European Geosciences Union in 2010. He carried out research, graduate and post-graduate teaching, and project management at the National Research Council of Italy, the Universities of Genoa, Florence and Parma, the Imperial College of Science and Technology, and Colorado State University. Author of 8 research books, 3 college texts, 3 essays, one novel and about 400 papers (more than 100 in SCI journals) in the fields of hydrology, water resources, river engineering, climate and glaciology, fluvial geomorphology, reliability analysis, stochastic processes, nonlinear dynamics and fractals.

Civil Engineer and Ph.D in Hydraulic Engineering, Umberto Sanfilippo is full time Researcher at Politecnico di Milano since 2002. Currently he is in charge of the course of Hydraulic Structures of the Civil and Environmental Engineering first level graduation. He is also Head of the Flowmeters Calibration Service at the Laboratorio di Idraulica "G.Fantoli" of Politecnico di Milano. He is author and co-author of about 90 papers, most of them on urban drainage. He is also co-author of a book on real time control of urban drainage systems and a book on pumps and pumping stations. He has also worked on four EU research projects and eleven Italian national and regional research projects.

Inhalt
ContentsForeword1. Introduction2. Flood Impact on Buildings2.1. Introduction2.2. Evaluation Criteria2.3. Comparison between Different Criteria3. Flood Impact on Human Beings Stability3.1. Introduction3.2. Models of Human Beings Stability4. Flood Impact on Mobilizable Objects5. Global Criteria for Impact Estimation5.1. Introduction5.2. New South Wales (Australia) Criteria5.3. ESCAP Criteria5.4. CEDEX (Spain) Criteria5.5. Indications of Po River Catchment Authorithy (Italy)5.6. FEMA (USA) Criteria5.7. Comparison of Different Approaches6. Hydrodynamic Criteria for Impact Evaluation6.1. Introduction6.2. Hydrodynamic Thresholds6.3. Implementation of Hydrodynamic Thresholds7. Flood Proofing Methods7.1. Overview7.2. First Level Classification (Strategic Planning)7.3. Design and Assessment Principles Introduction7.4. Temporary flood proofing as an emerging strategy for adaptation and regionalresilience7.5. Insurance discount, premium reduction and tax handle7.6. References8. Temporary flood proofing techniques planning8.1. Approach to arrangement and activation8.2. Decision factors The SENSO Model8.3. Temporary flood proofing response planning8.4. Defence lines38.5. A notable requirement case: Pisa (Italy) or where, probably, the modern temporaryflood proofing was started8.6. Effectiveness analysis: a path towards better design procedures8.7. References9. Temporary flood proofing devices analysis9.1. Recapitulating9.2. Description of temporary flood proofing proposed classes9.3. Emergency flood proofing techniques as 'transitional solutions' to support adaptationpolicies towards urban redevelopment and building restoration9.4. References10. Tests, Guidelines and Norms10.1.Overview10.2. Single Building Defence (Inner Line of Defence)10.3.Australian Guidelines10.4. European Guidelines10.5. FM Approval Standard10.6. SMARTeST project, Flood Resilience Technologies10.7. Performance Evaluation about Protection Devices according to CSTB10.8.DEFRA / Environment Agency10.9. Temporary Defences according to VKF10.10. Other Documents