Coursecode: wb3303
Coursename: Mechanisms
More information on:
http://www.ocp.tudelft.nl/tt/cadom/index.htm
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BLACKBOARD
ECTS creditpoints: 3 |
Faculty of
Mechanical Engineering and Marine Technology |
Lecturer(s): Klein Breteler, dr.ir. A.J. |
Tel.: 015 27
83130 |
Catalog data:
Kinematics, kinetostatics and dynamics of (co-planar) mechanisms, kinematic optimization,
numerical method (FEM), system drive+mechanism+process. |
Courseyear:
MSc 1e jaar
Semester: 1A, 1B
Hours p/w: 2
Other hours:
Assessment: exercise
Assessm.period(s): during course
(see academic calendar) |
Prerequisites:
|
Follow up:
wb5414-03 , wb3422-03 |
Detailed
description of topics:
Introduction: kinematic transfer function,
time-dependent motion, co-planar mechanism
Classical kinematics and differential
geometry. Terminology, selection of theory and graphical methods (1st and 2nd pole,
Mehmke, Aronhold, Euler/Savary, Bresse);
Finite element method in kinematic analysis.
Kinematic elements (co-ordinates and form parameters), continuity equations, generalized
transfer function (order 0, 1, 2), numerical calculation scheme, special elements (pair of
gears, cam and follower).
Kinematic optimization by gradient method.
Constraints (penalty functions). Derivatives calculated from FEM-equations. Protection of
the kinematic parameter space.
Inverse kinematics in the design of cam
mechanisms and manipulators
Kinetostatic and dynamic analysis of
mechanisms by FEM-method. Applied and internal forces (stress), virtual work. Modelling
support-, connection- and driving forces. Mass- and stiffness matrix. Equation of motion
(Wittenbauer I and II type). Deformation and vibration during motion. Motor models and
selection of a drive. Servo driven systems.
|
Course
material:
lecture notes Part 1: theory; Part 2: user manual of computer program |
References from
literature: |
Remarks
(specific information about assesment, entry requirements, etc.):
Individual
assesments are provided during the course. Both graphical methods and
numerical methods (using the computer program RUNMEC) will be exercised. |
Goals:
To describe a general theory for numerical analysis of the motion of mechanisms. The
FEM-method is adopted and will be applied to both kinematics and dynamics. Necessary
extensions are introduced for special types of elements and large mechanism motions. |
Computer use:
Use of a personal computer, at home or at the university. |
Laboratory
project(s): |
Design content:
Analysis of mechanism motion is an essential topic in mechanism design. It will be
required in various areas of mechanical engineering and machine design. |
Percentage of
design: 100% |