Dec 04, 2024  
2023-2024 Undergraduate Academic Catalog-June Update 
    
2023-2024 Undergraduate Academic Catalog-June Update [ARCHIVED CATALOG]

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MEC 2020 - Engineering Mechanics II: Dynamics

3 lecture hours 0 lab hours 3 credits
Course Description
This course is an introduction to the study of motion (kinematics) and forces (kinetics) which affect particles and rigid bodies. The Newtonian equilibrium equations introduced in the Statics course are extended to systems that are not in equilibrium (i.e., with velocity and acceleration). (prereq: MEC 1910 , MEC 2010 ) (quarter system prereq: ME 190, ME 1601, ME 2001)
Course Learning Outcomes
Upon successful completion of this course, the student will be able to:
  • Relate particle position, velocity, and acceleration using kinematic principles
  • Relate the motion of various points of a rigid body using kinematic principles
  • Draw free body and kinetic diagrams for systems in motion
  • Explain and be able to apply Newton’s laws of motion (kinetics) to particles and simple systems of rigid bodies
  • Explain and show how Newton’s laws of motion apply to the work-energy principle, the impulse-momentum principle and impact style problems
  • Apply kinematics and kinetics principles to systems in general plane motion such as planar mechanisms

Prerequisites by Topic
  • Statics
  • Computer programing

Course Topics
  • Position, velocity, acceleration of particles
  • Uniform rectilinear motion and acceleration of particles
  • Projectile motion of particles
  • Normal and tangential components
  • Polar coordinates
  • Relative motion of several particles
  • Kinetics of particles, rectilinear motion
  • Kinetics of particles, curvilinear motion
  • Principle of work and energy for a particle
  • Principle of impulse and momentum for a particle
  • Direct central impact of particle
  • Oblique central impact of particle
  • Planar kinematics of rigid bodies
  • Pure translation and rotation of rigid bodies
  • Rigid body rotation around a fixed axis
  • Absolute and relative velocity
  • Instantaneous center of rotation
  • Absolute and relative acceleration
  • Coriolis acceleration
  • Kinetics of rigid body motion forces and acceleration
  • Plane motion of rigid bodies energy and momentum
  • Principle of impulse and momentum rigid body
  • Conservation of angular momentum
  • Impulsive motion of rigid body
  • Eccentric impact of rigid body

Coordinator
Dr. Michael Sevier



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