Chapter Outline Shigley’s Mechanical Engineering Design.

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Presentation transcript:

Chapter Outline Shigley’s Mechanical Engineering Design

Free-Body Diagram Example 3-1 Shigley’s Mechanical Engineering Design

Free-Body Diagram Example 3-1 Fig. 3-1 Shigley’s Mechanical Engineering Design

Free-Body Diagram Example 3-1 Shigley’s Mechanical Engineering Design

Free-Body Diagram Example 3-1 Shigley’s Mechanical Engineering Design

Free-Body Diagram Example 3-1 Shigley’s Mechanical Engineering Design

Shear Force and Bending Moments in Beams Cut beam at any location x1 Internal shear force V and bending moment M must ensure equilibrium Fig. 3−2 Shigley’s Mechanical Engineering Design

Sign Conventions for Bending and Shear Fig. 3−3 Shigley’s Mechanical Engineering Design

Distributed Load on Beam Distributed load q(x) called load intensity Units of force per unit length Fig. 3−4 Shigley’s Mechanical Engineering Design

Relationships between Load, Shear, and Bending The change in shear force from A to B is equal to the area of the loading diagram between xA and xB. The change in moment from A to B is equal to the area of the shear-force diagram between xA and xB. Shigley’s Mechanical Engineering Design

Shear-Moment Diagrams Fig. 3−5 Shigley’s Mechanical Engineering Design

Moment Diagrams – Two Planes Fig. 3−24 Shigley’s Mechanical Engineering Design

Combining Moments from Two Planes Add moments from two planes as perpendicular vectors Fig. 3−24 Shigley’s Mechanical Engineering Design

Singularity Functions A notation useful for integrating across discontinuities Angle brackets indicate special function to determine whether forces and moments are active Table 3−1 Shigley’s Mechanical Engineering Design

Example 3-2 Fig. 3-5 Shigley’s Mechanical Engineering Design

Example 3-2 Shigley’s Mechanical Engineering Design

Example 3-2 Shigley’s Mechanical Engineering Design

Example 3-3 Fig. 3-6 Shigley’s Mechanical Engineering Design

Example 3-3 Shigley’s Mechanical Engineering Design

Example 3-3 Fig. 3-6 Shigley’s Mechanical Engineering Design

Normal stress is normal to a surface, designated by s Tangential shear stress is tangent to a surface, designated by t Normal stress acting outward on surface is tensile stress Normal stress acting inward on surface is compressive stress U.S. Customary units of stress are pounds per square inch (psi) SI units of stress are newtons per square meter (N/m2) 1 N/m2 = 1 pascal (Pa) Shigley’s Mechanical Engineering Design

Represents stress at a point Coordinate directions are arbitrary Stress element Represents stress at a point Coordinate directions are arbitrary Choosing coordinates which result in zero shear stress will produce principal stresses Shigley’s Mechanical Engineering Design

Two bodies with curved surfaces pressed together Contact Stresses Two bodies with curved surfaces pressed together Point or line contact changes to area contact Stresses developed are three-dimensional Called contact stresses or Hertzian stresses Common examples Wheel rolling on rail Mating gear teeth Rolling bearings Shigley’s Mechanical Engineering Design

Spherical Contact Stress Two solid spheres of diameters d1 and d2 are pressed together with force F Circular area of contact of radius a Shigley’s Mechanical Engineering Design

Spherical Contact Stress Pressure distribution is hemispherical Maximum pressure at the center of contact area Fig. 3−36 Shigley’s Mechanical Engineering Design

Spherical Contact Stress Maximum stresses on the z axis Principal stresses From Mohr’s circle, maximum shear stress is Shigley’s Mechanical Engineering Design

Spherical Contact Stress Plot of three principal stress and maximum shear stress as a function of distance below the contact surface Note that tmax peaks below the contact surface Fatigue failure below the surface leads to pitting and spalling For poisson ratio of 0.30, tmax = 0.3 pmax at depth of z = 0.48a Fig. 3−37 Shigley’s Mechanical Engineering Design

Cylindrical Contact Stress Two right circular cylinders with length l and diameters d1 and d2 Area of contact is a narrow rectangle of width 2b and length l Pressure distribution is elliptical Half-width b Maximum pressure Fig. 3−38 Shigley’s Mechanical Engineering Design

Cylindrical Contact Stress Maximum stresses on z axis Shigley’s Mechanical Engineering Design

Cylindrical Contact Stress Plot of stress components and maximum shear stress as a function of distance below the contact surface For poisson ratio of 0.30, tmax = 0.3 pmax at depth of z = 0.786b Fig. 3−39 Shigley’s Mechanical Engineering Design