ME 225A ¨C Dynamics ¨C Spring 2009
INFORMATION FOR STUDENTS
Instructor: Prof. Yong Shi Class
times/locations: M 1:00 ¨C 1:50 pm - EAS 230;
Office: EAS-207 TR
4:00 ¨C 4:50 pm - EAS 229A
E-mail: yshi2@stevens.edu
Telephone: (201) 216-5594
Course Purpose: This course is designed for mechanical engineering
students to complete their introduction to engineering mechanics of rigid
bodies; it follows the first course on statics with this second course on
dynamics.
Course
Description: Particle kinematics and kinetics, systems of particles,
work-energy, impulse and momentum, rigid-body kinematics, relative motion,
Coriolis acceleration, rigid-body kinetics, direct and oblique impact,
eccentric impact.
Prerequisites: Ma 116 (Mathematical
Textbook: Engineering Mechanics, Dynamics, 11th Edition, R. C. Hibbeler,
Pearson/Prentice Hall, 2006, ISBN 0-13-221504-7.
COURSE INFORMATION AND REQUIREMENTS:
1. Homework:
2. Quizzes & Exam: There will be three quizzes and one
written final exam, as noted in the schedule. These will be closed book and notes
exams, but a sheet of formulas will be provided. Make-ups will be given only for medical
reasons (with doctor¡¯s note) or prior arrangement with instructor.
3. Project: Teams will be formed to do a small
project on dynamics during the second half of the course. A report and
presentation will be prepared by each team.
4. Attendance: Class attendance is required.
Absences will be excused only for medical reasons (with doctor¡¯s note) or prior
arrangement with instructor. Absences beyond one will each result in 2.5%
subtracted from the final grade, with a maximum of four more permitted.
5. Grade: The final grade will be based on the
following components:
Homeworks 25%
of final grade
Quizzes
(3) 30%
Final Exam 30%
Project 10%
Attendance/pop
up 5%
ME 225A LECTURE CLASS SCHEDULE
(tentative)
|
Class Day
and Date |
Class Day
and Date |
|
1
Tues., Jan. 16 2
Thurs., Jan. 18
3
Mon., Jan. 22 4
Tues.., Jan. 23
5
Thurs., Jan. 25
6
Mon., Jan. 29 7
Tues., Jan. 30
8
Thurs., Feb. 1
9
Mon., Feb. 5 10
Tues., Feb. 6
11
Thurs., Feb. 8
12
Mon., Feb. 12 QUIZ 1 13
Tues., Feb. 13
14
Thurs., Feb. 15
15
Tues., Feb. 20 (Mon. hol., classes on Tues.) 16
Thurs., Feb. 22
17
Mon., Feb. 26 18
Tues., Feb. 27
19
Thurs., Mar. 1
20
Mon., Mar. 5 21
Tues., Mar. 6
|
22
Thurs., Mar. 8 (spring recess,
Mar. 12 - 16) 23
Mon., Mar. 19
QUIZ 2
24
Tues., Mar. 20 25
Thurs., Mar. 22 26
Mon., Mar. 26
27
Tues., Mar. 27 28
Thurs.., Mar. 29 29
Mon., Apr. 2
30
Tues., Apr. 3 31
Thurs., Apr. 5 32
Mon., Apr. 9
33
Tues., Apr. 10 34
Thurs., Apr. 12 35
Mon., Apr. 16
QUIZ 3
36
Tues., Apr. 17 37
Thurs., Apr. 19 38
Mon., Apr. 23
39
Tues., Apr. 24 40
Thurs., Apr. 26 41
Mon., Apr. 30
42
Tues., May 1 A May 3-15 period FINAL EXAM
|
Document Format
1. Write
all homework on lined paper, using one side only. Leave at least one inch
margins on page.
2. Provide
a cover page, with only the following information:
Student's
Name, Class Section, Homework Number, Due Date;
Stevens
Pledge Printed and Signed
3. Start each separate problem on a new page, unless the problem is very brief. If more than one problem is included on a given page, separate the problems with a horizontal dividing line.
4. Number
the pages consecutively, and staple all pages together in the proper order.
Numerical Problems
1. Write
down the problem statement, complete with sketches.
2. Identify
what is given, and what is to be found.
3. Draw
detailed Free Body Diagram, when appropriate.
3. Explain
calculation sequence in words (do not simply write down a series of equations),
if necessary.
4. If
equations are used, define each symbol in the equation.
5. Show algebraic form of each equation first, then calculation details, and identify the answer with a box.
6. Show
calculated results only to the number of decimal places which are appropriate
to the expected accuracy of the computations, considering the variability of
the data used and the inaccuracy of the analysis and/or calculations.
Graphs and Vector Diagrams
1. Label the axes.
2. Write
down the scales used and units for each parameter.
3. If
any measurements are taken from the graph and diagrams for subsequent
calculations, the corresponding points, lines, or angles must be shown on the
graph.
Drawings
1. Use
a sharpened pencil and make accurate sketches/drawings.
2. Use
a ruler or straight edge to draw straight lines, and a compass or template for
circles.
Note
that points are deducted for format omissions or errors, as well as conceptual
or computational errors.
MAJOR TOPICS
Introduction to dynamics,
kinematics of particles, curvilinear motions (chap. 12)
Kinetics of particles,
Work and energy
principles and conservation of energy for particles (chap. 14)
Principle of impulse and
momentum and impact for particles (chap. 15)
Planar kinematics of
rigid bodies, velocity and acceleration, Coriolis acceleration (chap. 16)
Planar kinetics of rigid
bodies: free body diagrams,
Planar kinetics for rigid
bodies: work and energy approach (chap. 18)
Planar kinetics for rigid
bodies: principle of impulse and momentum (chap. 19)
Introduction to
three-dimensional kinematics of rigid bodies (chap. 20)
COURSE OBJECTIVES
You
should be able to:
Write
kinematic equations of particles in rectangular and curvilinear coordinates.
Formulate
and solve problems dealing with motion of projectiles.
Recognize
forces and draw free body diagrams for particle and rigid body problems.
Use
work-energy approach to solve particle and rigid body problems.
Apply
principle of impulse and momentum to solve particle and rigid body
problems.
Understand
the relevance of particle models and apply them in dynamics.
See
the application of rigid body analysis to linkage kinematics and kinetics.
Understand
the practical relevance of relative motion of rigid body dynamics.
Use
linear and angular momentum conservation in solving kinetic problems.
Use
linear momentum and coefficient of restitution in impact problems.
Use
Write
equations of dynamic equilibrium using free body diagrams and inertia forces.