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Bridge Engineering: Classifications, Design Loading, and Analysis Methods [Mīkstie vāki]

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(Department of Civil and Environmental Engineering, Waseda University, Tokyo, Japan), (Department of Civil and Environmental Engineering, International Center for Science and Engineering Programs, Waseda University, Tokyo, Japan)
  • Formāts: Paperback / softback, 292 pages, height x width: 229x152 mm, weight: 430 g
  • Izdošanas datums: 12-May-2017
  • Izdevniecība: Butterworth-Heinemann Inc
  • ISBN-10: 0128044322
  • ISBN-13: 9780128044322
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Bridge Engineering: Classifications, Design Loading, and Analysis MethodsPalielināt
  • Formāts: Paperback / softback, 292 pages, height x width: 229x152 mm, weight: 430 g
  • Izdošanas datums: 12-May-2017
  • Izdevniecība: Butterworth-Heinemann Inc
  • ISBN-10: 0128044322
  • ISBN-13: 9780128044322
Citas grāmatas par šo tēmu:
Permanent link: https://www.kriso.lv/db/9780128044322.html
Keywords:

Bridge Engineering: Classifications, Design Loading, and Analysis Methods begins with a clear and concise exposition of theory and practice of bridge engineering, design and planning, materials and construction, loads and load distribution, and deck systems. This is followed by chapters concerning applications for bridges, such as: Reinforced and Prestressed Concrete Bridges, Steel Bridges, Truss Bridges, Arch Bridges, Cable Stayed Bridges, Suspension Bridges, Bridge Piers, and Bridge Substructures. In addition, the book addresses issues commonly found in inspection, monitoring, repair, strengthening, and replacement of bridge structures.

  • Includes easy to understand explanations for bridge classifications, design loading, analysis methods, and construction
  • Provides an overview of international codes and standards
  • Covers structural features of different types of bridges, including beam bridges, arch bridges, truss bridges, suspension bridges, and cable-stayed bridges
  • Features step-by-step explanations of commonly used structural calculations along with worked out examples

Papildus informācija

This accessible guide offers a clear and concise exposition of all the theoretical and practical considerations involved in bridge engineering
About the Authors ix
1 Introduction of Bridge Engineering
1(30)
1.1 Introduction
1(2)
1.2 Bridge Components
3(2)
1.3 Bridge Classification
5(22)
1.4 Selection of Bridge Types
27(2)
1.5 Exercises
29(2)
References
30(1)
2 Bridge Planning and Design
31(28)
2.1 Introduction
31(1)
2.2 Bridge Design Philosophy
31(2)
2.3 Bridge Survey
33(1)
2.4 Bridge Planning and Geometric Design
33(2)
2.5 Bridge Design Methods
35(2)
2.6 Earthquake- and Wind-Resistant Designs
37(12)
2.7 Bridge Design Specifications
49(2)
2.8 Structural Design and Design Drawings
51(1)
2.9 Bridge Esthetic Design and a Case Study
51(4)
2.10 Exercises
55(4)
References
56(3)
3 Materials for Bridge Constructions
59(12)
3.1 Introduction
59(1)
3.2 Stone
59(1)
3.3 Wood or Timbers
60(1)
3.4 Steel
61(3)
3.5 Concrete
64(2)
3.6 New Composite Materials
66(1)
3.7 Case Study---A Famous Timber Bridge in Japan and Its Assessment
66(3)
3.8 Exercises
69(2)
References
69(2)
4 Loads and Load Distribution
71(8)
4.1 Introduction
71(1)
4.2 Dead Load
72(1)
4.3 Live Load
72(6)
4.4 Impact
78(1)
4.5 Wind
79(6)
4.6 Temperature
80(1)
4.7 Seismic Load
80(1)
4.8 Snow and Ice
81(1)
4.9 Construction Load
81(1)
4.10 Creep and Shrinkage of Concrete
82(1)
4.11 Combination of Loads for Bridge Design
82(1)
4.12 Exercises
82(3)
References
83(2)
5 Bridge Deck Systems
85(12)
5.1 Introduction
85(1)
5.2 Layout of the Deck Surface
85(2)
5.3 Bridge Pavement
87(1)
5.4 Drainage System
88(1)
5.5 Waterproofing System
89(1)
5.6 Bridge Expansion Joint
90(2)
5.7 Unseating Prevention System
92(3)
5.8 Guard Railings
95(1)
5.9 Other Accessories
95(1)
5.10 Exercises
96(1)
References
96(1)
6 Reinforced and Prestressed Concrete Bridges
97(14)
6.1 Introduction
97(1)
6.2 Materials
98(2)
6.3 Reinforced Concrete Bridges
100(4)
6.4 Prestressed Concrete Bridges
104(6)
6.5 Exercises
110(1)
References
110(1)
7 Steel Bridges
111(26)
7.1 Introduction
111(1)
7.2 Connecting Methods
111(3)
7.3 Steel-Concrete Composite Bridges
114(11)
7.4 Case Study---A Research on Steel---Concrete Composite Beams Subjected to Hogging Moment
125(10)
7.5 Summary
135(1)
7.6 Exercises
135(2)
References
135(2)
8 Truss Bridges
137(18)
8.1 Introduction
137(1)
8.2 Truss Bridge Terminology
138(3)
8.3 Types of Trusses
141(4)
8.4 The Design of Truss Bridges
145(3)
8.5 Case Study---Tokyo Gate Bridge
148(3)
8.6 Exercises
151(4)
References
153(2)
9 Arch Bridges
155(20)
9.1 Introduction
155(1)
9.2 Structure Features
156(1)
9.3 Arch Bridge Classification
157(8)
9.4 Erection of Arch Bridges
165(5)
9.5 Case Study: Preservation of Masonry Arch Bridges
170(2)
9.6 Exercises
172(3)
References
173(2)
10 Cable-Stayed Bridges
175(20)
10.1 Introduction
175(1)
10.2 Cable-Stayed Bridge Classification
176(8)
10.3 Configuration
184(7)
10.4 Analysis of Cable-Stayed Bridges
191(1)
10.5 Construction of Cable-Stayed Bridges
191(3)
10.6 Exercises
194(1)
References
194(1)
11 Suspension Bridges
195(18)
11.1 Introduction
195(1)
11.2 Structural Components
196(1)
11.3 Suspension Bridge Classification
197(6)
11.4 Configuration
203(5)
11.5 Analysis of Suspension Bridges
208(1)
11.6 Suspension Bridge Construction
209(1)
11.7 Exercises
210(3)
References
211(2)
12 Bridge Bearings and Substructures
213(14)
12.1 Introduction
213(1)
12.2 Bearings
214(7)
12.3 Abutments
221(2)
12.4 Piers
223(1)
12.5 Foundations
224(2)
12.6 Exercises
226(1)
References
226(1)
13 Inspection, Monitoring, and Assessment
227(18)
13.1 Introduction
227(1)
13.2 Bridge Inspection
227(6)
13.3 Bridge Monitoring
233(3)
13.4 Structural Assessment
236(1)
13.5 Exercises
237(1)
References
238(1)
Appendix
238(5)
Liam J. Butler
Further Reading
243(2)
14 Repair, Strengthening, and Replacement
245(28)
14.1 Introduction
245(2)
14.2 Repair and Strengthening of Concrete Bridges
247(2)
14.3 Repair and Strengthening of Steel Bridges
249(6)
14.4 Bridge Replacement
255(1)
14.5 Case Study: A Strengthening Method for Railways Bridges in Japan
256(14)
14.6 Exercises
270(3)
References
270(3)
Index 273
Lin Weiwei Assistant Professor Faculty of Science and Engineering, Department of Civil and Environmental Engineering / International Center for Science and Engineering Programs(ICSEP) Teruhiko Yoda is on the faculty of Waseda University, where he holds the chair professorship in the Department of Civil and Environmental Engineering. He has authored and co-authored more than 20 technical books and over 300 articles dealing with the problems of the structural mechanics and bridge engineering.