| 《结构设计原理》基于高等院校土木工程专业、道路桥梁工程专业教学指导委员会的要求,按照中华人民共和国国家标准和现行的交通运输部行业标准与最新设计规范《公路桥涵设计规范》(JTG 1360—2004)、《公路钢筋混凝土及预应力混凝土桥涵设计规范》(YFG D62—2004)、《公路圬工桥涵设计规范》(JTG D6l—2005)进行编写的,适应于包括香港、澳门等地的国内外相关的专业技术人员使用。 本书是在作者长期教学实践和创建“结构设计原理”国家精品课程、充分汲取国内外优秀中英文教材精华的基础上完成的,注重理论联系实际。符号和计量单位按国家标准。 |
| 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 concept 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 flexural member 3.6 Doubly reinforced flexural 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 of tension control stress and loss of prestressing 12.4 Calculation and checking of stress for the flexural member of prestressed concrete 12.5 Checking of anti-cracking 12.6 Calculation of deformation and setting of pre-camber 12.7 Calculation of the end in the anchorage zone 12.8 Design of simply-supported prestressed concrete beams Chapter 13 Partially Prestressed Concrete Flexurai Members 13.1 Concept and characteristics of PPC members 13.2 Classification and mechanic characteristic of PPC structure 13.3 The design calculation for category B of PPC 13.4 Design of PPC flexural member crack allowed 13.5 Example for calculation of the hollow-core deck of prestressed concrete Chapter 14 Calculation of the Fiexural Members of Unbonded Prestressed Concrete 14.1 Flexural strength of unbonded prestressed concrete members 14.2 Calculation of flexural members of unbonded partially prestressed concrete 14.3 Design of a cross section of a flexural member of unbonded partially prestressed concrete member 14.4 Structure of flexural members of unbonded partially prestressed concrete Part 3 Masonry Structures Chapter 15 Basic Concepts and Materials of Masonry Structures 15.1 Basic concepts of masonry structures 15.2 Materials of the masonry 15.3 The strength and displacement of the masonry Chapter 16 Calculation of Load-carrying Capacity of Masonry Structures 16.1 Principles of calculation 16.2 Load-carrying capacity of the compressed member 16.3 Sectional local compression, bended, and shear calculations of the load-carrying capacity Appendix References |
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