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Der Betonfertigteilbau ist eine der innovativsten Bauweisen - hier werden neue Betone, Bewehrungen und Herstellverfahren erstmals angewendet, denn das Fertigteilwerk bietet hervorragende Voraussetzungen für die industrielle Herstellung. Dieses Buch führt in die Bauweise ein und vermittelt alles notwendige Wissen für die Konstruktion, Berechnung und Bemessung. Auch die geschichtliche Entwicklung und der Stand der europäischen Normung werden aufgezeigt. Der Dreh- und Angelpunkt für den wirtschaftlichen und fehlerfreien Einsatz von Betonfertigteilen ist der fertigungs- und montagegerechte…mehr
Der Betonfertigteilbau ist eine der innovativsten Bauweisen - hier werden neue Betone, Bewehrungen und Herstellverfahren erstmals angewendet, denn das Fertigteilwerk bietet hervorragende Voraussetzungen für die industrielle Herstellung. Dieses Buch führt in die Bauweise ein und vermittelt alles notwendige Wissen für die Konstruktion, Berechnung und Bemessung. Auch die geschichtliche Entwicklung und der Stand der europäischen Normung werden aufgezeigt. Der Dreh- und Angelpunkt für den wirtschaftlichen und fehlerfreien Einsatz von Betonfertigteilen ist der fertigungs- und montagegerechte Entwurf. Neben den zu beachtenden Randbedingungen werden typische Fertigteilkonstruktionen zur Diskussion gestellt. Die Verbindungen der Betonfertigteile sind gerade bei Horizontallasten besonders zu beachten, daher wird die Aussteifung von Fertigteilgebäuden ausführlich behandelt. Besonderheiten der Bemessung, z. B. Lager, Konsolen und Stützenstöße, werden detailliert dargestellt. Ein zunehmend wichtiger Anwendungsbereich für Betonfertigteile ist der Fassadenbau, welchem ein eigenes Kapitel gewidmet ist. Abschließend wird auf die Fertigung eingegangen, um beim Leser das Verständnis für die Bauweise zu vertiefen. Für die vorliegende 2. Auflage wurde das Werk vom erweiterten Autorenteam komplett überarbeitet. Das Buch ist eine Einführung und ein praktisches Arbeitsmittel mit Beispielen für Bauingenieure und Architekten gleichermaßen.
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Autorenporträt
Alfred Steinle (1936-2017) turned the lecture notes of Prof. Dr.-Ing. Volker Hahn, which dated from the early 1970s, into a manuscript that became the starting point for this book. After a number of years in bridge-building, Alfred Steinle also became heavily involved in precast concrete construction at Züblin. His theoretical work covered bridge-building with torsion and section deformations in box-girder bridges and in precast concrete structures within the scope of the 6M system with corbels, notched beam ends and pocket foundations. In addition, he was a key figure in many precast concrete projects such as the 6M schools, the University of Riyadh, schools with foamed concrete wall panels in Iraq, Züblin House and the construction of a modern automated precasting plant. Alfred Steinle retired in 1999 and by that time he had risen to the post of authorised signatory in the engineering office at Züblin's head office. Hubert Bachmann (b. 1959) began his career in a precasting plant in 1976 as an apprentice for concrete and precast concrete construction. After studying structural engineering and completing his doctorate at the University of Karlsruhe, he accepted a post in the structural engineering office of Ed. Züblin AG in Stuttgart in 1993, where he has worked ever since. His duties have included the detailed design of structures of all kinds plus research and development in the civil and structural engineering sectors. He has been presenting the series of Hahn lectures on precast concrete structures at the University of Stuttgart since 2003. Mathias Tillmann (b. 1970) has been an engineering and standards consultant at Fachvereinigung Deutscher Betonfertigteilbau e.V. (FDB) since 2007 and technical director since 2008. He specialised in structural engineering during his studies at RWTH Aachen University. After attaining his diploma, he worked as a project engineer, structural engineer and designer. Mathias Tillmann has written numerous brochures, advisory documents and specialist articles on the subject of precast concrete. All three authors have been or still are verymuch involved in construction industry organisations, many technical boards and national and international standards committees concerned with precast concrete construction.
Inhaltsangabe
Preface Introduction 1 General 1.1The advantages of factory production 1.2 Historical development 1.3 European standardisation 2 Design of Precast Concrete Structures 2.1 General 2.2 Tolerances and calculations for fit 2.3 Production 2.4 Transport and erection 2.5 Sustainability 2.6 Design examples 3 Stability of Precast Concrete Structures 3.1 General 3.2 Loads on stability components 3.3 Loadbearing members for stability 3.4 Distribution of horizontal loads 3.5 Analysis of stability components 3.6 Construction details 4 Precast Concrete Elements 4.1 General 4.2 Floor and roof elements 4.3 Beams 4.4 Columns 4.5 Walls 4.6 Foundations 5 Connections for Precast Concrete Construction 5.1 General 5.2 Purlin supports 5.3 Roof beam supports 5.4 Floor slab supports 5.5 Downstand beam supports 5.6 Wall element supports 5.7 Balcony slabs 5.8 Stair supports 5.9 Column/foundation 6 Individual Design Issues 6.1 General 6.2 Patch loads 6.3 Supports 6.4 Column butt joints 6.5 Wall/floor connections 6.6 Shear dowels 6.7 Welded connections 6.8 Bolted connections and screw couplers 6.9 Other forms of connection 6.10 Transport fixings 6.11 Transferring shear forces across joints 6.12 Floor diaphragms and shear walls 6.13 Shear forces in floor elements 6.14 Notched supports 6.15 Corbels 6.16 Analysis of lateral buckling 6.17 Design for fire 6.18 Pretensioning 7 Precast Concrete Façades 7.1 General 7.2 Conceptual design 7.3 Surface finishes 7.4 Joint waterproofing 7.5 Concrete sandwich panels 7.6 Suspended façade panels 7.7 Further developments for concrete façades 7.8 Building physics 7.9 Case studies 8 Production 8.1 Production methods 8.2 Concretes for precast concrete elements 8.3 Heat treatment and curing 8.4 Reinforcement 8.5 Pretensioning in prestressing beds 8.6 Quality assurance IndexPreface Introduction 1 General 1.1The advantages of factory production 1.2 Historical development 1.3 European standardisation 2 Design of Precast Concrete Structures 2.1 General 2.2 Tolerances and calculations for fit 2.3 Production 2.4 Transport and erection 2.5 Sustainability 2.6 Design examples 3 Stability of Precast Concrete Structures 3.1 General 3.2 Loads on stability components 3.3 Loadbearing members for stability 3.4 Distribution of horizontal loads 3.5 Analysis of stability components 3.6 Construction details 4 Precast Concrete Elements 4.1 General 4.2 Floor and roof elements 4.3 Beams 4.4 Columns 4.5 Walls 4.6 Foundations 5 Connections for Precast Concrete Construction 5.1 General 5.2 Purlin supports 5.3 Roof beam supports 5.4 Floor slab supports 5.5 Downstand beam supports 5.6 Wall element supports 5.7 Balcony slabs 5.8 Stair supports 5.9 Column/foundation 6 Individual Design Issues 6.1 General 6.2 Patch loads 6.3 Supports 6.4 Column butt joints 6.5 Wall/floor connections 6.6 Shear dowels 6.7 Welded connections 6.8 Bolted connections and screw couplers 6.9 Other forms of connection 6.10 Transport fixings 6.11 Transferring shear forces across joints 6.12 Floor diaphragms and shear walls 6.13 Shear forces in floor elements 6.14 Notched supports 6.15 Corbels 6.16 Analysis of lateral buckling 6.17 Design for fire 6.18 Pretensioning 7 Precast Concrete Façades 7.1 General 7.2 Conceptual design 7.3 Surface finishes 7.4 Joint waterproofing 7.5 Concrete sandwich panels 7.6 Suspended façade panels 7.7 Further developments for concrete façades 7.8 Building physics 7.9 Case studies 8 Production 8.1 Production methods 8.2 Concretes for precast concrete elements 8.3 Heat treatment and curing 8.4 Reinforcement 8.5 Pretensioning in prestressing beds 8.6 Quality assurance Index
Preface Introduction 1 General 1.1The advantages of factory production 1.2 Historical development 1.3 European standardisation 2 Design of Precast Concrete Structures 2.1 General 2.2 Tolerances and calculations for fit 2.3 Production 2.4 Transport and erection 2.5 Sustainability 2.6 Design examples 3 Stability of Precast Concrete Structures 3.1 General 3.2 Loads on stability components 3.3 Loadbearing members for stability 3.4 Distribution of horizontal loads 3.5 Analysis of stability components 3.6 Construction details 4 Precast Concrete Elements 4.1 General 4.2 Floor and roof elements 4.3 Beams 4.4 Columns 4.5 Walls 4.6 Foundations 5 Connections for Precast Concrete Construction 5.1 General 5.2 Purlin supports 5.3 Roof beam supports 5.4 Floor slab supports 5.5 Downstand beam supports 5.6 Wall element supports 5.7 Balcony slabs 5.8 Stair supports 5.9 Column/foundation 6 Individual Design Issues 6.1 General 6.2 Patch loads 6.3 Supports 6.4 Column butt joints 6.5 Wall/floor connections 6.6 Shear dowels 6.7 Welded connections 6.8 Bolted connections and screw couplers 6.9 Other forms of connection 6.10 Transport fixings 6.11 Transferring shear forces across joints 6.12 Floor diaphragms and shear walls 6.13 Shear forces in floor elements 6.14 Notched supports 6.15 Corbels 6.16 Analysis of lateral buckling 6.17 Design for fire 6.18 Pretensioning 7 Precast Concrete Façades 7.1 General 7.2 Conceptual design 7.3 Surface finishes 7.4 Joint waterproofing 7.5 Concrete sandwich panels 7.6 Suspended façade panels 7.7 Further developments for concrete façades 7.8 Building physics 7.9 Case studies 8 Production 8.1 Production methods 8.2 Concretes for precast concrete elements 8.3 Heat treatment and curing 8.4 Reinforcement 8.5 Pretensioning in prestressing beds 8.6 Quality assurance IndexPreface Introduction 1 General 1.1The advantages of factory production 1.2 Historical development 1.3 European standardisation 2 Design of Precast Concrete Structures 2.1 General 2.2 Tolerances and calculations for fit 2.3 Production 2.4 Transport and erection 2.5 Sustainability 2.6 Design examples 3 Stability of Precast Concrete Structures 3.1 General 3.2 Loads on stability components 3.3 Loadbearing members for stability 3.4 Distribution of horizontal loads 3.5 Analysis of stability components 3.6 Construction details 4 Precast Concrete Elements 4.1 General 4.2 Floor and roof elements 4.3 Beams 4.4 Columns 4.5 Walls 4.6 Foundations 5 Connections for Precast Concrete Construction 5.1 General 5.2 Purlin supports 5.3 Roof beam supports 5.4 Floor slab supports 5.5 Downstand beam supports 5.6 Wall element supports 5.7 Balcony slabs 5.8 Stair supports 5.9 Column/foundation 6 Individual Design Issues 6.1 General 6.2 Patch loads 6.3 Supports 6.4 Column butt joints 6.5 Wall/floor connections 6.6 Shear dowels 6.7 Welded connections 6.8 Bolted connections and screw couplers 6.9 Other forms of connection 6.10 Transport fixings 6.11 Transferring shear forces across joints 6.12 Floor diaphragms and shear walls 6.13 Shear forces in floor elements 6.14 Notched supports 6.15 Corbels 6.16 Analysis of lateral buckling 6.17 Design for fire 6.18 Pretensioning 7 Precast Concrete Façades 7.1 General 7.2 Conceptual design 7.3 Surface finishes 7.4 Joint waterproofing 7.5 Concrete sandwich panels 7.6 Suspended façade panels 7.7 Further developments for concrete façades 7.8 Building physics 7.9 Case studies 8 Production 8.1 Production methods 8.2 Concretes for precast concrete elements 8.3 Heat treatment and curing 8.4 Reinforcement 8.5 Pretensioning in prestressing beds 8.6 Quality assurance Index
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