Plastics are high-performance materials of wide use in the built environment. Their versatile technical properties are particularly fascinating. A broad range of form-giving and finishing processes makes plastic especially interesting for complex geometries in combination with digital planning processes. Following the pioneering plastic structures of the 1970s, a number of spectacular buildings have in recent years highlighted the outstanding technical and aesthetic potential of the material.
Until now, however, there has been no systematic treatment of the use of plastic in architecture. This book seeks to fill that gap by providing an introduction to the structural and design possibilities of plastic. It introduces the material and its specific characteristics, describes various types of plastic in terms of their relevance for building, explains processing technologies and presents typical products and components. A concise presentation of twenty-five international built projects – organized by the type of application and the plastic involved – documents the broad range of plastic in architecture. Finally, a look ahead at the future describes the current state of the art in materials research.
Innehållsförteckning
Preface
1 The development of plastic architecture
PRINCIPLES
2 Material properties of plastics
2.1 Forming characteristics and the manufacture of building elements
2.2 Resistance to environmental effects
2.3 Mechanical properties
2.4 Thermal properties
2.5 Flammability and fire performance
2.6 Additives, fillers and reinforcing materials
3. Basics of plastics
3.2 Polymer structure
3.3 The morphology of macromolecules
3.4 The classification of plastics according to their degree of cross-linking
3.5 Synthesising techniques
4. Plastics and their manufacture
4.1 Elastomers
4.2 Thermoplastics
4.2.1 Types
4.2.2 Manufacture
4.2.3 Working methods
4.2.4 Recycling
4.3 Thermosets
4.3.1 Material components
4.3.2 Manufacture
4.3.3 Properties
CONSTRUCTION
5. Finished and semi-finished products
5.1 Solid sheets and panels
5.2 Profiled sheets and panels
5.3 Sandwich panels
5.4 Foams
5.5 Profiles
5.6 Special products
6. Building with plastics
6.1 Thermoplastics
6.1.1 Screwing
6.1.2 Clamping
6.1.3 Bonding
6.1.4 Welding
6.2 Thermosetting plastics
6.2.1 Screwing
6.2.2 Bonding
6.2.3 Dimensioning
6.2.4 Stability and durability
CASE STUDIES
7 Plastics as building envelope
Chanel Mobile Art Pavilion
Hong Kong, China; Tokyo, Japan; New York, USA
BMW Bubble
Frankfurt and Berlin, Germany
Kunsthaus Graz
Graz, Austria
Railway station Emsdetten
Emsdetten, Germany
Idee Workstation
Tokyo, Japan
Reiss Headquarters
London, United Kingdom
Fiberline Composites factory and offices
Middelfart, Denmark
Farben des Konsums
Berlin, Germany
Laban Creekside
London, United Kingdom
Terminal V
Lauterach, Austria
Forum Soft
Yverdon, Switzerland
Polymer Engineering Centre
Melbourne, Australia
Dornier Museum
Friedrichshafen, Germany
Congress centre and auditorium
Badajoz, Spain
8 Plastics as building structure
Plastic tower sculpture
Stuttgart, Germany
D-Tower
Doetinchem, Netherlands
Hoofddorp bus station
Hoofddorp, Netherlands
Roof Yitzhak Rabin Centre
Tel Aviv, Israel
GRP-Glass-Pavilion
Düsseldorf, Germany
9 Plastics as building structure and envelope
Clip-On
Utrecht, Netherlands
Eiertempel
Bern, Switzerland
Five Bubbles
Vienna, Austria
fg 2000
Altenstadt, Germany
Futuro
different locations worldwide
MYKO
Weimar and Rostock, Germany
Novartis Campus reception building
Basel, Switzerland
10 Future developments
High-performance material for supporting structures
High-performance material for building envelopes
Composite materials
Reinforcement of supporting structures
Joining technologies appropriate to the material
New production methods
Technology transfer
Glossary
Bibliography
About the authors
Acknowledgements
Name and building index
Subject index
Illustration credits
Om författaren
Prof. Dr.-Ing. Stephan Engelsmann ist Bauingenieur. Er studierte Bauingenieurwesen an der TU München und Architektur an der University of Bath. Er war wissenschaftlicher Mitarbeiter bei Jörg Schlaich und arbeitete in verschiedenen Ingenieurbüros. Er ist heute Professor für konstruktives Entwerfen und Tragwerkslehre an der Staatlichen Akademie der Bildenden Künste Stuttgart und er ist Gründungspartner im Ingenieurbüro Engelsmann Peters Beratende Ingenieure in Stuttgart.
Valerie Spalding studierte Architektur an der RWTH Aachen. Sie arbeitete in verschiedenen Architekturbüros im In- und Ausland, darunter James Carpenter Design Associates in New York. Seit 2005 ist sie wissenschaftliche Mitarbeiterin an der Staatlichen Akademie der Bildenden Künste Stuttgart und forscht zum Thema Bauen mit Kunststoffen.
Dr.-Ing. Stefan Peters ist Bauingenieur. Er studierte an der Universität Stuttgart und war Mitarbeiter in verschiedenen Ingenieurbüros, unter anderem Werner Sobek Ingenieure. Nach einer Tätigkeit als wissenschaftlicher Mitarbeiter an der Universität Stuttgart bei Jan Knippers von 2000 bis 2006 gründete er mit Stephan Engelsmann das Ingenieurbüro Engelsmann Peters Beratende Ingenieure in Stuttgart.