| | Drawing equipment and use of instruments. Lettering, Geometric construction, Sketching and shape description. Basic descriptive geometry, Developments and intersections. Axonometric, oblique and perspective drawings, Multiview projection, Principal views, Conventional practice, and sectional views. Auxiliary views. Dimensioning techniques. Parallel: Introduction to computer drawing, Drawing aids, Geometrical construction, and the appropriate commands of text, editing, plotting, sections, layers, pictorial views, and dimensioning. Auxiliary views.
| 1988-2010 | | | Mechanical engineering drawing conventions and abbreviations, various systems of size description, including precision dimensioning, fastening elements, standard organization and preparation of engineering drawings, assembly and detailed drawings,design applications.
| 1988-2007 | | | Meaning, phases, evaluation, considerations of design, stress analysis, deflection analysis, static strength and theories of failure, fatigue strength. Design of fasteners and connections; riveted joints, bolts and screws, force-deflection diagrams of bolted connections. Welded joints. Mechanical springs, helical, leaf, torsional spring shafts. | 1988-1998 | | | Role of failure prevention in Mechanical design. Stress and deformation. Classical theories of failure. Notches and notch sensitivity. Fracture Mechanics: Rowan –Irwin relationship, Linear elastic fracture mechanics, Elastic stress field approach, Energy balance approach, J-Integral. Fatigue: Low cycle fating, High cycle fatigue, and remaining life. Creep and some mathematical; models. Wear.
| 1988-2009 | | | Force systems (2D and 3D), equilibrium of particles and rigid bodies (2D and 3D), structures (trusses, frames and machines), distributed forces (centroids and centers of mass), beams (shearing force and bending moment diagrams), friction, moments of inertia and virtual work.
| 1992-1996 | | | Axial loading, Material properties obtained from tensile tests, Stresses and strains due to axial loading, Thermal Stresses, Elementary theory of torsion, Solid and hollow shafts, Thin-walled tubes, Rectangular cross-section, Stresses in beams due to bending, shear and combined forces. Composite beams, Analysis of plane stress, Mohr’s Circle, Combined stresses, Thin-walled pressure vessels, Deflection of beams, Buckling of columns, Energy Methods. | 1994-1999 | | | Rolling contact bearings, selection, mounting and enclosure. Lubrication and journal bearings. Clutches, coupling and brakes. Gearing : Geometry, kinematics gear trains and force analysis. design of spur, helical, bevel and worm gears. multi-speed gear boxes. design and analysis of belts, ropes, chains, term project. | 1988-1998 | | | Review of stress, analysis. Theories of failure. Power transmission shafts. Tension and shear. Connections and selection of bolts. Helical tension and compression spring design. Weld analysis and design. Selection of rolling element bearings. Gears geometry, Force and stress analysis. Mechanical couplings. Flexible power transmission elements. | 1995-1997 | | |
This course gives the student the necessary knowledge of the principles of mapping and designing of orthotics and prosthetics . It also provides the student information about drawings equipment , related standards perspective view .
| 2000-2009 | | |
The course aims to familiarize the student with the necessary tools for design Execution. It is divided into two sections;
First section: deals with free – hand architectural drawing - Ink drawing
- Drawing on various surfaces (tracing paper, butter paper, white carton)
- Exercises in perspective (projection, frontal view, plans, 3 dimensional drawing, isometric, and axonometric)
- The importance of proportions
- International standards for different materials
- Knowledge of symbols and footnotes Second Section: The student is taught to use computer programs such as
Autodesk and Auto CAD to execute 2D and 3D designs.
| 2008-2010 |
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