Page 56 - Academic Handbook FKM 2017-2018
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SYNOPSIS the industrial training must be recorded in a log book
Students in third year are required to undergo provided by the faculty, which will be evaluated by
industrial training for a minimum of 10 weeks at the the supervisors. Five credit-hours are given for this
designated organisation. During the industrial industrial training. Students must show satisfactory
training, students are given continuous supervision by attendance and discipline in order to pass this
an industrial supervisor as well as supervisor course. The faculty’ supervisor may visit the students
appointed by the faculty. Daily activities throughout during the training period.
YEAR 3 COURSES - PROGRAMME CORE
BMCG 3113 MECHANICS OF SOLIDS II b. Hibbeler, R.C., 2011, Mechanics of Materials,
LEARNING OUTCOMES SI Ed., Prentice Hall.
At the end of this course, students should be able to: c. Gere, J.M., 2012, Mechanics of Materials, CL
LO1 Analyse plane-strain problems, strain Engineering.
measurements, stress-strain for pressure
vessels and finally apply yield criteria to
avoid elastic failure or yielding. BMCG 3313 ENGINEERING DESIGN
LO2 Analyse and solve the deformation of LEARNING OUTCOMES
structural members based on double At the end of this course, students should be able to:
integration and energy methods. LO1 Explain and apply an appropriate design
LO3 Evaluate and solve buckling problem of method at the particular design phase in the
structural members under compressive axial course of developing a practical solution of
load and plastic collapse of mechanical an engineering design problem.
members due to various loading conditions. LO2 Develop a practical design solution through a
SYNOPSIS systematic investigation of the engineering
Transformation of plane-strain and measurements of design problem.
strain. Pressure vessels: thin, thick and compound LO3 Communicate effectively in written, oral and
cylinders. Yield criteria for ductile and brittle visual means in a technical setting.
materials. Deflection of beams. Strain energy: SYNOPSIS
Energy concept and Castigliano’s theorem. Column: This course covers Engineering Design process
Euler’s buckling stress and Secant Formula. Plastic started from problems analysis, Formulating Design
deformation due to axial, bending and torsional problems, Concept Design, Configuration Design,
loadings and residual stresses. Parametric Design, Detail Design and Prototypes
REFERENCES Development. Suitable methods such as QFD,
a. Beer, F.P, Johnston, E.R., Dewolf, J.T., and Weighted Objective Method will be used at the
Mazurek, D.F., 2012, Mechanics of Materials, particular design stage. Engineering Economics
6th edition. McGraw-Hill. aspect of product, human factor, ethic and safety in
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