Course

Unit 1

Introduction to Engineering Graphics and 3D Modeling.

Introduction to BIS of Engineering Drawing – Significance of 3D modeling – Introduction to 3D Modeling Software

 Unit 2

Orthographic and Isometric Projections in 3D.

Understanding orthographic projections of points, lines, planes, and solids in 3D – Developing 2D projections of 3D models. Developing sectional views of 3D models of solids – Developing isometric projections from 3D models of solids – Real-world applications of orthographic projections

Unit 3

Development of Lateral Surfaces.

Developing lateral surfaces of right regular prisms, cylinders, pyramids, and cones – Understanding the development of surfaces in 3D models – Real-world applications of surface development

Unit 4

Advanced 3D Modeling Techniques.

Advanced modeling techniques in 3D Modeling Software – Creating complex 3D models using multiple tools and techniques. – Applications of advanced 3D modeling techniques in various industries – Exporting 3D models for prototyping and manufacturing

Note: The course is designed to provide students with a comprehensive understanding of engineering graphics, including 2D and 3D modeling techniques. The course will also cover various real-world applications of these techniques and how they are used in different industries. Students will be expected to complete assignments and projects using 3D Modeling Software (Autodesk® Fusion 360®). The classroom learning will be supplemented with a workbook, where the students shall have manual drawing practice for all projection-related topics.

Course Objectives

• To develop a comprehensive understanding of the motion of particles and rigid bodies in two and three dimensions using principles of kinematics and kinetics.
• To apply Newtonian mechanics and energy/momentum principles to solve engineering problems involving dynamic systems, including rotational and gyroscopic motion.

Course Outcomes

CO1: Analyze the rectilinear and curvilinear motion of particles and rigid bodies using tangential, normal, and polar coordinate systems.

CO2: Apply Newton’s laws of motion, D’Alembert’s principle, and work-energy methods to solve problems in dynamics.

CO3: Evaluate linear and angular momentum for particles and rigid bodies, including the application of conservation principles.

CO4: Compute mass moment of inertia and analyze three-dimensional motion and gyroscopic effects in rigid bodies.

CO-PO Mapping

J.L. Meriam and L.G. Kraige, Engineering Mechanics: Dynamics, Wiley.

R.C. Hibbeler, Engineering Mechanics: Dynamics, Pearson.

Bedford and W. Fowler, Engineering Mechanics: Dynamics, Pearson.