Venice Shall Rise Again (e-bog) af Teatini, Pietro
Teatini, Pietro (forfatter)

Venice Shall Rise Again e-bog

546,47 DKK (inkl. moms 683,09 DKK)
The city of Venice, Italy, has been subjected to periodic flooding, or acqua alta, for centuries. Venice Shall Rise Again presents a unique proposition to halt this flooding. Based on years of work and experiment, experts Gambolati and Teatini describe an innovative yet technologically simple, economically inexpensive, and environmentally friendly project to raise Venice by 25-30 cm over ten ye...
E-bog 546,47 DKK
Forfattere Teatini, Pietro (forfatter)
Forlag Elsevier
Udgivet 18 oktober 2013
Længde 100 sider
Genrer Architecture
Sprog English
Format pdf
Beskyttelse LCP
ISBN 9780124201484
The city of Venice, Italy, has been subjected to periodic flooding, or acqua alta, for centuries. Venice Shall Rise Again presents a unique proposition to halt this flooding. Based on years of work and experiment, experts Gambolati and Teatini describe an innovative yet technologically simple, economically inexpensive, and environmentally friendly project to raise Venice by 25-30 cm over ten years by injecting seawater into 650-1000 m deep geological formations. This project would be conducted under conditions of absolute safety, stability and integrity conserving the unique artistic and architectural patrimony of this deeply beloved city. Beginning with a brief history of the Venetian Republic, Venice Shall Rise Again addresses the actions undertaken by Venice to protect the city and the lagoon from the sea and land attack for more than a millennium, including the MoSE project, a system of mobile barriers presently under construction. Detailed in its engineering details and ideas, but with enough background information and context to help the interested reader understand the concepts, this book will be of interest to all readers concerned about the fate of Venice. Provides a history of the technical measures taken by the Venetian Republic to preserve the lagoon and the city or Venice Details technical specifications of a new method to secure Venice against periodic flooding