Engineering Basic Mechanics Ⅰ Statics is divided into 14 chapters, including fundamentals of statics and force analysis of objects; coplanar concurrent force system and couple system; coplanar general force system; space force system; friction; fundamental concepts of bar deformation; axial tension and compression; shear and torsion; geometric properties of cross sections; plane bending; state of stress and theories of strength; combined deformation; energy method; stability of columns.

In each chapter, the principles are applied first to simple, then to more complicated situations. The fundamental conception, formula and method are explained in detail. This book can provide the student with a clear and thorough presentation of the theory and applications of engineering mechanics.

This book can be used as a textbook for the basic course of mechanics in mechanical, civil engineering, shipping, mechanics, aviation, water conservancy and other related majors. It can also be used as a reference for engineering technicians of related areas.

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Chapter 1 Fundamentals of Statics and Force Analysis of Objects
  1.1 Basic concepts of statics
  1.2 Fundamental principles of statics
  1.3 Constraint and reactive forces
  1.4 Force analysis and free-body diagram
  Problems
Chapter 2 Coplanar Concurrent Force System and Couple System
  2.1 Reduction and equilibrium of coplanar concurrent force system
  2.2 Coplanar couple system
  Problems
Chapter 3 Coplanar General Force System
  3.1 The translation theorem of forces
  3.2 Reduction of the coplanar general force system
  3.3 Reduced resultant of coplanar general force system and resultant moment theorem
  3.4 Equilibrium of coplanar general force system
  3.5 Reduction and equilibrium of coplanar parallel force system
  3.6 Equilibrium of composite bodies
  3.7 Coplanar truss analysis
  Problems
Chapter 4 Space Force System
  4.1 Decomposition and projection of space force
  4.2 Reduction and equilibrium of space concurrent force system
  4.3 Space couple system
  4.4 Moment of a space force about a point and a specified axis
  4.5 Reduction of space general force system
  4.6 Equilibrium equations for space general force system
  Problems
Chapter 5 Friction
  5.1 Sliding friction
  5.2 Friction angle and self-locking phenomenon
  5.3 Equilibrium problems with friction
  5.4 Rolling resistance
  Problems
Chapter 6 Fundamental Concepts of Bar Deformation
  6.1 Tasks of deformation statics mechanics
  6.2 Simplification of engineering members
  6.3 Internal force and stress
  6.4 Displacement and strain
  6.5 Basic forms of bar deformation
Chapter 7 Axial Tension and Compression
  7.1 Introduction of axial tension and compression
  7.2 Internal forces in axial tension or compression
  7.3 Stress in axial tension or compression
  7.4 Elastic deformation in axial tension or compression
  7.5 Mechanical properties of materials in tension and compression
  7.6 Strength calculation in axial tension or compression
  Problems
Chapter 8 Shear and Torsion
  8.1 The concept of shear
  8.2 Practical calculation of shear
  8.3 Practical calculations for bearing
  8.4 The concept of torsion
  8.5 Torque and torque diagram
  8.6 Torsion of thin-walled cylinders
  8.7 Stress and deformation during torsion of circular shafts
  8.8 Torsional strength and rigidity
  Problems
Chapter 9 Geometric Properties of Cross Sections
  9.1 Static moment of area and centroid
  9.2 Moment of inertia, product of inertia and radius of gyration
  9.3 Parallel axis theorem
  9.4 Transformation equation and principal moment of inertia
  Problems
Chapter 10 Plane Bending
  10.1 Introduction
  10.2 Internal force in beams
  10.3 Shear force and bending moment diagrams
  10.4 Relations among shear force, bending moment and loads
  10.5 Normal stress on cross section in pure bending
  10.6 Shear stress in bending
  10.7 Calculation of strength
  10.8 Displacement and rigidity condition of beams
  10.9 Deflection of beams
  Problems
Chapter 11 State of Stress and Theories of Strength
  11.1 State of stress
  11.2 Analysis of plane stress
  11.3 Mohr circle for plane stress
  11.4 Triaxial stress state
  11.5 Generalized Hooke law and volumetric strain
  11.6 Strain energy density of triaxial stress
  11.7 Theories of strength
  Problems
Chapter 12 Combined Deformation
  12.1 Introduction
  12.2 Skew bending
  12.3 Combined axial load and bending
  12.4 Combined bending and torsion
  Problems
Chapter 13 Energy Method
  13.1 Strain energy of a bar
  13.2 Mohr theorem
  13.3 Diagram multiplication method for Mohr integration
  13.4 Castigliano's theorem
  Problems
Chapter 14 Stability of Columns
  14.1 Introduction
  14.2 Critical compressive force of slender column with pin support
  14.3 Critical compressive force of slender column with other constraints
  14.4 Diagram of critical stress
  14.5 Calculation of stability of columns
  Problems
Reference