This book consists of statics,kinematics,kinetics,and mechanics of materials.The main contents of the book include: statics of a particle and of a rigid body,friction,kinematics of a particle and of a rigid body in plane motion,resultant motion of aparticle,kinetics of a particle and of a rigid body in plane motion,mechanicalproperties of materials,axial tension and compression of bars,torsion of shafts,bending of beams,stress analysis and theories of strength,combined loadings,andstability of columns. The book can be used as an English,Chinese,or bilingual textbook of engineeringmechanics for the student majoring in aeronautical,mechanical,civil,and hydraulicengineering. 本书由静力学、运动学、动力学和材料力学组成。主要内容包括:质点静力学和刚体静力学、摩擦、质点运动学和刚体平面运动学、质点合成运动、质点动力学和刚体平面动力学、材料机械性能、杆的轴向拉伸与压缩、轴的扭转、梁的弯曲、应力分析与强度理论、组合载荷和压杆稳定。 本书可作为高等院校航空、机械、土木和水利等学科专业学生的英文、中文或双语工程力学教材。
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目录
Preface 前言 English Edition Chapter 1 Fundamental Concepts of Theoretical Mechanics 1.1 What Is Theoretical Mechanics 1.2 Basic Concepts 1.3 General Principles Chapter 2 Statics of Particle 2.1 System of Concurrent Forces 2.2 Resultant of Coplanar Concurrent Forces 2.3 Equilibrium of Coplanar Concurrent Forces 2.4 Resultant of Spatial Concurrent Forces 2.5 Equilibrium of Spatial Concurrent Forces Problems Chapter 3 Reduction of Force System 3.1 Moment of Force about Point 3.2 Moment of Force about Given Axis 3.3 Principle of Moments 3.4 Components of Moment of Force about Point 3.5 Moment of Couple 3.6 Resultant of Couples 3.7 Equivalence of Force Acting on Rigid Body 3.8 Reduction of Force System Problems Chapter 4 Statics of Rigid Body 4.1 Equilibrium of Rigid Body 4.2 Equilibrium of Two-Dimensional Rigid Body 4.3 Two-Force and Three-Force Bodies 4.4 Planar Trusses 4.5 Equilibrium of Three-Dimensional Rigid Body Problems Chapter 5 Friction 5.1 Types of Friction 5.2 Sliding Friction 5.3 Angles of Friction 5.4 Problems Involving Sliding Friction 5.5 Rolling Resistance Problems Chapter 6 Kinematics of Particle 6.1 Motion of Particle 6.2 Motion of Particle Represented by Vector 6.3 Motion of Particle Represented by Rectangular Coordinates 6.4 Motion of Particle Represented by Natural Coordinates Problems Chapter 7 Kinematics of Rigid Body in Plane Motion 7.1 Plane Motion of Rigid Body 7.2 Translation 7.3 Rotation about Fixed Axis 7.4 General Plane Motion Problems Chapter 8 Resultant Motion of Particle 8.1 Motion of Particle 8.2 Rates of Change of Vector 8.3 Resultant of Velocities 8.4 Resultant of Accelerations Problems Chapter 9 Kinetics of Particle 9.1 Newtons Second Law of Motion 9.2 Equations of Motion of Particle 9.3 Method of Inertia Force for Particle in Motion 9.4 Method of Work and Energy for Particle in Motion 9.5 Method of Impulse and Momentum for Particle in Motion Problems Chapter 10 Kinetics of Rigid Body in Plane Motion 10.1 Motion for System of Particles 10.2 Motion of Mass Center of System of Particles 10.3 Motion of System of Particles about Its Mass Center 10.4 Equations of Motion for Rigid Body in Plane Motion 10.5 Method of Inertia Force for Rigid Body in Plane Motion 10.6 Method of Work and Energy for Rigid Body in Plane Motion 10.7 Method of Impulse and Momentum for Rigid Body in Plane Motion Problems Chapter 11 Fundamental Concepts of Mechanics of Materials 11.1 What Is Mechanics of Materials 11.2 Basic Assumptions of Materials 11.3 External Forces 11.4 Internal Forces 11.5 Stresses 11.6 Strains 11.7 Deformations of Members Problems Chapter 12 Mechanical Properties of Materials 12.1 Tensile or Compressive Test 12.2 Tension of Low-Carbon Steel 12.3 Ductile and Brittle Materials 12.4 Stress-Strain Curve of Ductile Materials without Distinct Yield Point 12.5 Percent Elongation and Percent Reduction in Area 12.6 Hookes Law 12.7 Mechanical Properties of Materials in Compression Chapter 13 Axial Tension and Compression of Bars 13.1 Definition of Axial Tension and Compression 13.2 Axial Force 13.3 Normal Stress on Cross Section 13.4 Saint-Venants Principle 13.5 Normal and Shearing Stresses on Oblique Section 13.6 Normal Strain 13.7 Deformation of Axially Loaded Bar 13.8 Statically Indeterminate Axially Loaded Bar 13.9 Design of Axially Loaded Bar 13.10 Stress Concentrations Problems Chapter 14 Torsion of Shafts 14.1 Definition of Torsion 14.2 Twisting Moment 14.3 Hookes Law in Shear 14.4 Shearing Stress on Cross Section of Circular Shaft 14.5 Normal and Shearing Stresses on Oblique Section of Circular Shaft 14.6 Angle of Twist 14.7 Statically Indeterminate Circular Shaft 14.8 Design of Circular Shaft Problems Chapter 15 Shearing Force and Bending Moment of Beams 15.1 Definition of Bending 15.2 Shearing-Force and Bending-Moment Diagrams 15.3 Relations between Distributed Load, Shearing Force, and Bending Moment 15.4 Relations between Concentrated Load, Shearing Force, and Bending Moment Problems Chapter 16 Normal Stress and Shearing Stress in Beams 16.1 Types of Bending 16.2 Normal Stresses on Cross Section in Pure Bending 16.3 Normal and Shearing Stresses on Cross Section in Transverse-Force Bending 16.4 Design of Prismatic Beams in Bending Problems Chapter 17 Deflection and Slope of Beams 17.1 Deformation of Beams 17.2 Method of Integration 17.3 Method of Superposition 17.4 Statically Indeterminate Beams Problems Chapter 18 Stress Analysis and Theories of Strength 18.1 State of Stress 18.2 Transformation of Plane Stress 18.3 Principal Stresses for Plane Stress 18.4 Maximum Shearing Stress for Plane Stress 18.5 Stresses in Pressure Vessels 18.6 Generalized Hookes Law 18.7 Theories of Strength under Plane Stress Problems Chapter 19 Combined Loadings 19.1 Definition of Combined Loadings 19.2 Stress in Bar Subject to Eccentric Tension or Compression 19.3 Stress in I-Section Beam Subject to Transverse-Force Bending 19.4 Stress in Beam Subject to Bending and Axial Tension/Compression 19.5 Stress in Shaft Subject to Torsion and Bending Problems Chapter 20 Stability of Columns 20.1 Definition of Buckling 20.2 Critical Load of Long Slender Columns under Centric Loadwith Pin Supports 20.3 Critical Load of Long Slender Columns under Centric Load with Other Supports 20.4 Critical Stress of Long Slender Columns under Centric Load 20.5 Critical Stress of Intermediate Length Columns under Centric Load 20.6 Design of Columns under Centric Load Problems References Appendix Ⅰ Centers of Gravity and Centroids Ⅰ.1 Center of Gravity and Centroid of Plate Ⅰ.2 Center of Gravity and Centroid of Composite Plate Ⅰ.3 Center of Gravity and Centroid of 3D Body Ⅰ.4 Center of Gravity and Centroid of 3D Composite Body Appendix Ⅱ Mass Moments of Inertia Ⅱ.1 Moment of Inertia and Radius of Gyration Ⅱ.2 Parallel-Axis Theorem Appendix Ⅲ Geometrical Properties of Areas Ⅲ.1 First Moment and Centroid Ⅲ.2 First Moment and Centroid of Composite Area Ⅲ.3 Moment of Inertia and Polar Moment of Inertia Ⅲ.4 Radius of Gyration and Polar Radius of Gyration Ⅲ.5 Product of Inertia Ⅲ.6 Parallel-Axis Theorem Ⅲ.7 Moment of Inertia and Polar Moment of Inertia of Commonly-Used Areas Appendix Ⅳ Geometrical Properties of Rolled-Steel Shapes Ⅳ.1 I Steel Ⅳ.2 Channel Steel Ⅳ.3 Equal Angle Steel Ⅳ.4 Unequal Angle Steel Appendix Ⅴ Deflections and Slopes of Beams 中文版 第1章 理论力学的基本概念 1.1 什么是理论力学 1.2 基本概念 1.3 普遍原理 第2章 质点静力学 2.1 汇交力系 2.2 平面汇交力的合成 2.3 平面汇交力的平衡 2.4 空间汇交力的合成 2.5 空间汇交力的平衡 习题 第3章 力系的简化 3.1 力对点之矩 3.2 力对轴之矩 3.3 力矩定理 3.4 力对点之矩的分量 3.5 力偶矩 3.6 力偶的合成 3.7 作用于刚体上力的等效 3.8 力系的简化 习题 第4章 刚体静力学 4.1 刚体平衡 4.2 二维刚体的平衡 4.3 二力和三力物体 4.4 平面桁架 4.5 三维刚体的平衡 习题 第5章 摩擦 5.1 摩擦分类 5.2 滑动摩擦 5.3 摩擦角 5.4 含有滑动摩擦的问题 5.5 滚动摩阻 习题 第6章 质点运动学 6.1 质点的运动 6.2 质点运动的矢量表示 6.3 质点运动的直角坐标表示 6.4 质点运动的自然坐标表示 习题 第7章 刚体平面运动学 7.1 刚体平面运动 7.2 平移 7.3 定轴转动 7.4 一般平面运动 习题 第8章 质点合成运动 8.1 质点的运动 8.2 矢量的变化率 8.3 速度的合成 8.4 加速度的合成 习题 第9章 质点动力学 9.1 牛顿第二运动定律 9.2 质点运动方程 9.3 运动质点的惯性力法 9.4 运动质点的功-能法 9.5 运动质点的冲量-动量法 习题 第10章 刚体平面动力学 10.1 质点系的运动 10.2 质点系质心的运动 10.3 质点系相对质心的运动 10.4 平面运动刚体的运动方程 10.5 平面运动刚体的惯性力法 10.6 平面运动刚体的功-能法 10.7 平面运动刚体的冲量-动量法 习题 第11章 材料力学的基本概念 11.1 什么是材料力学 11.2 材料的基本假设 11.3 外力 11.4 内力 11.5 应力 11.6 应变 11.7 构件的变形 习题 第12章 材料机械性能 12.1 拉伸或压缩试验 12.2 低碳钢拉伸 12.3 塑性和脆性材料 12.4 没有明显屈服点的塑性材料的应力-应变曲线 12.5 伸长率和断面收缩率 12.6 胡克定律 12.7 材料压缩机械性能 第13章 杆的轴向拉伸与压缩 13.1 轴向拉伸与压缩的定义 13.2 轴力 13.3 横截面上的正应力 13.4 圣维南原理 13.5 斜截面上的正应力和剪应力 13.6 线应变 13.7 轴向加载杆的变形 13.8 静不定轴向加载杆 13.9 轴向加载杆的设计 13.10 应力集中 习题 第14章 轴的扭转 14.1 扭转的定义 14.2 扭矩 14.3 剪切胡克定律 14.4 圆轴横截面上的剪应力 14.5 圆轴斜截面上的正应力和剪应力 14.6 扭转角 14.7 静不定圆轴 14.8 圆轴的设计 习题 第15章 梁的剪力与弯矩 15.1 弯曲的定义 15.2 剪力和弯矩图 15.3 分布载荷、剪力和弯矩之间的关系 15.4 集中载荷、剪力和弯矩之间的关系 习题 第16章 梁的正应力与剪应力 16.1 弯曲的类型 16.2 纯弯曲梁横截面上的正应力 16.3 横力弯曲梁横截面上的正应力和剪应力 16.4 等截面弯曲梁的设计 习题 第17章 梁的挠度与转角 17.1 梁的变形 17.2 积分法 17.3 叠加法 17.4 静不定梁 习题 第18章 应力分析与强度理论 18.1 应力状态 18.2 平面应力状态变换 18.3 平面应力状态的主应力 18.4 平面应力状态的最大剪应力 18.5 压力容器中的应力 18.6 广义胡克定律 18.7 平面应力状态强度理论 习题 第19章 组合载荷 19.1 组合载荷的定义 19.2 偏心拉伸或压缩杆的应力 19.3 横力弯曲工字梁的应力 19.4 弯曲与拉压梁的应力 19.5 扭转与弯曲轴的应力 习题 第20章 压杆稳定 20.1 失稳的定义 20.2 两端铰支中心加载细长压杆的临界载荷 20.3 其他支撑中心加载细长压杆的临界载荷 20.4 中心加载细长压杆的临界应力 20.5 中心加载中长压杆的临界应力 20.6 中心加载压杆的设计 习题 参考文献 附录Ⅰ 重心与形心 Ⅰ.1 薄板的重心与形心 Ⅰ.2 组合薄板的重心与形心 Ⅰ.3 三维物体的重心与形心 Ⅰ.4 三维组合物体的重心与形心 附录Ⅱ 转动惯量 Ⅱ.1 转动惯量与回转半径 Ⅱ.2 平行移轴定理 附录Ⅲ 截面几何性质 Ⅲ.1 静矩与形心 Ⅲ.2 组合截面的静矩与形心 Ⅲ.3 惯性矩与极惯性矩 Ⅲ.4 惯性半径与极惯性半径 Ⅲ.5 惯性积 Ⅲ.6 平行移轴定理 Ⅲ.7 常用截面的惯性矩与极惯性矩 附录Ⅳ 型钢几何性质 Ⅳ.1 工字钢 Ⅳ.2 槽钢 Ⅳ.3 等边角钢 Ⅳ.4 不等边角钢 附录Ⅴ 常用梁的挠度与转角
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