结构设计原理(第二版) / 21世纪交通版高等学校教材
¥60.00定价
作者: 张建仁
出版时间:2013-03
出版社:人民交通出版社
- 人民交通出版社
- 9787114104343
- 36750
- 46176159-5
- 平装
- 16开
- 2013-03
- 920
- 576
- 工学
- 土木工程
- U448.142.5
- 土木工程、路桥
- 本科
内容简介
张建仁、刘小燕主编的《结构设计原理(第2版)》为国家级精品课程教材,且为双语教材。本书根据高等学校土木工程、道路桥梁与渡河工程专业结构设计原理课程的教学要求,参照中华人民共和国国家和交通行业现行标准与规范,对公路桥涵所用的钢筋混凝土结构、预应力混凝土结构、圬工结构的各种基本受力构件进行全面介绍。本书再版是在使用实践、充分听取任课教师意见的基础上进行的。
《结构设计原理(第2版)》可以作为高等学校土木工程、道路桥梁与渡河工程专业用的双语教材,也可供相关专业的外国留学生使用,同时也可供从事桥梁设计与管理的国内外专业技术人员参考。
《结构设计原理(第2版)》可以作为高等学校土木工程、道路桥梁与渡河工程专业用的双语教材,也可供相关专业的外国留学生使用,同时也可供从事桥梁设计与管理的国内外专业技术人员参考。
目录
General Introduction
0.1 Introduction
0.2 Basic Concepts
0.3 Characteristics of the course and guidance for how to learn the course
Part 1 Reinforced Concrete Structures
Chapter 1 Basic Concepts of Reinforced Concrete Structures and Physical and Mechanical Properties of Materials
1.1 Basic concepts of reinforced concrete structures
1.2 Concrete
1.3 Steel reinforcement
1.4 Bonding between steel reinforcement and concrete
Chapter 2 Structural Probabilistic Design Method and Principles
2.1 Introduction
2.2 Basic concepts of probabilistic limit state design method
2.3 Calculation principles of the CHBC
2.4 Values of material strength
2.5 Actions, specified actions and combinations of action effects
Chapter 3 Calculation of Load-carrying Capacity of Flexural Member
3.1 Basic concept of flexural members
3.2 Construction and shape of cross-section for flexural members
3.3 Failure mode and mechanical behavior of whole process for flexural members
3.4 Basic calculation principles of load-carrying capacity of normal section for flexural member
3.5 Singly-reinforced rectangular section fle~ural member
3.6 Doubly reinforced fiexural members with rectangular section
3.7 T-shaped flexural members
Chapter 4 Calculation of Inclined Section's Load-carrying Capacity of Flexural Members
4.1 Inclined section's performance characteristics and failure forms of flexural members
4.2 Factors affecting the shear capacity of diagonal section
4.3 The calculation of inclined section's shear capacity of flexural members
4.4 Inclined section's flexural capacity of flexural members
4.5 Load-carrying capacity checking of the whole beam and the detailing requirements
Chapter 5 Calculation of Load-carrying Capacity of Torsion Members
5.1 Overview
5.2 Failure characteristics and capacity calculation of pure torsion members
5.3 The bearing capacity of rectangular section member under the action of bending, shear and torsion
5.4 Torsion member of T-shaped and I-shaped cross section
5.5 Torsion member with box section
5.6 Construction requirements
Chapter 6 Calculation of Strength of Axially Loaded Members
6.1 Introduction
6.2 Calculation on axially loaded members with longitudinal bars and tied stirrups
6.3 Axially loaded members with longitudinal bars and spiral stirrups
Chapter 7 Calculation of Strength of Eccentrically Loaded Members
7.1 Failure modes and mechanical characteristics
7.2 Buckling of eccentrically loaded members
7.3 Eccentrically loaded rectangular member
7.4 Eccentrically loaded members with I-shape and T-shape sections
7.5 Eccentrically loaded circle member
Chapter 8 Calculation of Load-carrying Capacity of Tensile Members
8.1 Overview
8.2 Calculation of load-carrying capacity of axial tensile members
8.3 Calculation of strength of eccentric tensile members
Chapter 9 Calculation of Stress, Cracking and Deflection of Reinforced Concrete Flexural Members
9.1 Introduction
9.2 Transformed section
9.3 Check of stress
9.4 Check of cracks and crack width of flexural members
9.5 Deformation (deflection) check of flexural members
9.6 Durability of concrete structure
Chapter 10 Local Compression
10.1 The mode and mechanism of failure under local compression
10.2 Enhancement coefficient of concrete strength for local compression
10.3 Calculation of local compression zone
Part 2 Prestressed Concrete Structure
Chapter 11 Basic Concepts and Materials of Prestressed Concrete Structures
11.1 Introduction
11.2 Methods and equipment for prestressing construction
11.3 Materials of prestressed concrete structures
Chapter 12 Design and Calculation of Prestressed Concrete Flexural Members
12.1 Mechanical phases and calculation characteristics
12.2 Calculation of ultimate load-carrying capacity
12.3 Calculation o
0.1 Introduction
0.2 Basic Concepts
0.3 Characteristics of the course and guidance for how to learn the course
Part 1 Reinforced Concrete Structures
Chapter 1 Basic Concepts of Reinforced Concrete Structures and Physical and Mechanical Properties of Materials
1.1 Basic concepts of reinforced concrete structures
1.2 Concrete
1.3 Steel reinforcement
1.4 Bonding between steel reinforcement and concrete
Chapter 2 Structural Probabilistic Design Method and Principles
2.1 Introduction
2.2 Basic concepts of probabilistic limit state design method
2.3 Calculation principles of the CHBC
2.4 Values of material strength
2.5 Actions, specified actions and combinations of action effects
Chapter 3 Calculation of Load-carrying Capacity of Flexural Member
3.1 Basic concept of flexural members
3.2 Construction and shape of cross-section for flexural members
3.3 Failure mode and mechanical behavior of whole process for flexural members
3.4 Basic calculation principles of load-carrying capacity of normal section for flexural member
3.5 Singly-reinforced rectangular section fle~ural member
3.6 Doubly reinforced fiexural members with rectangular section
3.7 T-shaped flexural members
Chapter 4 Calculation of Inclined Section's Load-carrying Capacity of Flexural Members
4.1 Inclined section's performance characteristics and failure forms of flexural members
4.2 Factors affecting the shear capacity of diagonal section
4.3 The calculation of inclined section's shear capacity of flexural members
4.4 Inclined section's flexural capacity of flexural members
4.5 Load-carrying capacity checking of the whole beam and the detailing requirements
Chapter 5 Calculation of Load-carrying Capacity of Torsion Members
5.1 Overview
5.2 Failure characteristics and capacity calculation of pure torsion members
5.3 The bearing capacity of rectangular section member under the action of bending, shear and torsion
5.4 Torsion member of T-shaped and I-shaped cross section
5.5 Torsion member with box section
5.6 Construction requirements
Chapter 6 Calculation of Strength of Axially Loaded Members
6.1 Introduction
6.2 Calculation on axially loaded members with longitudinal bars and tied stirrups
6.3 Axially loaded members with longitudinal bars and spiral stirrups
Chapter 7 Calculation of Strength of Eccentrically Loaded Members
7.1 Failure modes and mechanical characteristics
7.2 Buckling of eccentrically loaded members
7.3 Eccentrically loaded rectangular member
7.4 Eccentrically loaded members with I-shape and T-shape sections
7.5 Eccentrically loaded circle member
Chapter 8 Calculation of Load-carrying Capacity of Tensile Members
8.1 Overview
8.2 Calculation of load-carrying capacity of axial tensile members
8.3 Calculation of strength of eccentric tensile members
Chapter 9 Calculation of Stress, Cracking and Deflection of Reinforced Concrete Flexural Members
9.1 Introduction
9.2 Transformed section
9.3 Check of stress
9.4 Check of cracks and crack width of flexural members
9.5 Deformation (deflection) check of flexural members
9.6 Durability of concrete structure
Chapter 10 Local Compression
10.1 The mode and mechanism of failure under local compression
10.2 Enhancement coefficient of concrete strength for local compression
10.3 Calculation of local compression zone
Part 2 Prestressed Concrete Structure
Chapter 11 Basic Concepts and Materials of Prestressed Concrete Structures
11.1 Introduction
11.2 Methods and equipment for prestressing construction
11.3 Materials of prestressed concrete structures
Chapter 12 Design and Calculation of Prestressed Concrete Flexural Members
12.1 Mechanical phases and calculation characteristics
12.2 Calculation of ultimate load-carrying capacity
12.3 Calculation o
