TY  - GEN
N2  - This book explores membrane materials as a means of translating natural and renewable resources into a more flexible, dynamic, and reactive architectural skin. It represents the first time that energy-saving design has been addressed systematically in relation to lightweight building systems and tensile membranes. Understanding of the energetic behavior of membranes and foils used as a building envelope is a fundamental theme, as it is the integration of flexible photovoltaics in membranes, as well as the exploitation of water and wind resources. A theoretical, methodological framework for consciously designing the membrane life cycle is presented. The authors cross-cut and combine exploration of climate-based design methodology and life cycle thinking strategies. Both active and passive systems are investigated, referring to alternative productive resources like sun, wind, and water. Case studies are brought forward in the books second half, highlighting energy lightness for an increasingly dematerialized architecture and addressing inherent issues. Four main research and development paths are presented, the first two focusing on advancements in facade materials and Photovoltaic systems applicable to membrane architecture, the third referring to fog and dew harvesting and the fourth dealing with the future frontier of flexible transparency and designs for well-being through a passive solar system.
DO  - 10.1007/978-3-031-08154-5
DO  - doi
AB  - This book explores membrane materials as a means of translating natural and renewable resources into a more flexible, dynamic, and reactive architectural skin. It represents the first time that energy-saving design has been addressed systematically in relation to lightweight building systems and tensile membranes. Understanding of the energetic behavior of membranes and foils used as a building envelope is a fundamental theme, as it is the integration of flexible photovoltaics in membranes, as well as the exploitation of water and wind resources. A theoretical, methodological framework for consciously designing the membrane life cycle is presented. The authors cross-cut and combine exploration of climate-based design methodology and life cycle thinking strategies. Both active and passive systems are investigated, referring to alternative productive resources like sun, wind, and water. Case studies are brought forward in the books second half, highlighting energy lightness for an increasingly dematerialized architecture and addressing inherent issues. Four main research and development paths are presented, the first two focusing on advancements in facade materials and Photovoltaic systems applicable to membrane architecture, the third referring to fog and dew harvesting and the fourth dealing with the future frontier of flexible transparency and designs for well-being through a passive solar system.
T1  - Lightweight energy :membrane architecture exploiting natural renewable resources /
DA  - 2023.
CY  - Cham :
AU  - Zanelli, Alessandra.
AU  - Monticelli, Carol,
AU  - Jakica, Nebojsa.
AU  - Fan, Zhengyu.
CN  - NA2542.3
PB  - Springer,
PP  - Cham :
PY  - 2023.
N1  - 2.2 Description of the Materials' Flowchart for the SOFT Cell Production
ID  - 1453444
KW  - Architecture and energy conservation.
KW  - Architecture
KW  - Membranes (Technology)
KW  - Sustainable architecture.
KW  - Sustainable buildings.
KW  - Lightweight construction.
KW  - Renewable natural resources.
SN  - 9783031081545
SN  - 3031081544
TI  - Lightweight energy :membrane architecture exploiting natural renewable resources /
LK  - https://univsouthin.idm.oclc.org/login?url=https://link.springer.com/10.1007/978-3-031-08154-5
UR  - https://univsouthin.idm.oclc.org/login?url=https://link.springer.com/10.1007/978-3-031-08154-5
ER  -