Course Objectives:
To teach the basic principles of thermodynamics.
To teach thermodynamics with real-world engineering examples so that the students would understand the applications of thermodynamics in engineering practice.
To develop an intuitive understanding of thermodynamics by emphasizing the physics and the physical arguments that underpin the theory.
Course Outcomes: At the end of the course, the student will be able to
CO 1: explain the basic concepts of thermodynamics such as system, state, state postulate, equilibrium, process, and cycle.
CO 2: demonstrate the procedures for determining thermodynamic properties of pure substances from tables of property data.
CO 3: solve the energy balance problems for closed systems of incompressible substances and ideal gases.
CO 4: solve energy balance problems for common steady-flow devices such as nozzles, compressors, turbines, throttling valves, mixing chambers, and heat exchangers.
CO 5: determine the expressions for thermal efficiencies and coefficients of performance for reversible heat engines, heat pumps, and refrigerators.
drive.google.com/drive/folders/1HSoo3D6fCS4T1g8egm6P58Jcp2Ztdqq1
Course Objectives:
To develop graphics skills for communication of concepts, ideas, and design of engineering products.
To expose the students to existing national standards related to technical drawings and computer-aided drafting.
Course Outcomes: At the end of the course, the student will be able to
CO 1: illustrate the fundamentals of engineering drawing and draw orthographic projections of points and lines.
CO 2: draw orthographic projections of planes and simple solids.
CO 3: draw orthographic projections of sectioned solids and development of surfaces.
CO 4: draw the isometric view of simple solids.
CO 5: demonstrate drafting skills using CAD software.
Course Objectives:
To teach the basic principles of hydraulics and the equations that govern the fluid flow.
To solve numerous real-world engineering examples including examples from marine engineering.
To develop an intuitive understanding of hydraulics by emphasizing physics.
Course Outcomes: At the end of the course, the students will be able to
CO 1: analyze the stability of various types of crafts and submarines.
CO 2: distinguish between various types of flow by using flow patterns and vorticity.
CO 3: solve for pressure field, velocity field, and shear stress field around the simple models of hydrofoil, screw propeller, and ship hull.
CO 4: test the simple models of hydrofoil, screw propeller, and ship hull for dynamic similarity.
CO 5: solve for the lift and the drag of a submerged vessel in an unbounded fluid.
drive.google.com/drive/folders/1dLdg6rTlrimtYPq-ru1ivWHIqVn6QP2A
Course Objectives:
To demonstrate the measurement of fluid property called viscosity and flow property called velocity.
To analyze the static stability of ship models.
To determine the flow rate of water through pipes and canals.
Course Outcomes: At the end of the course, the students will be able to
CO 1: measure the fluid property called viscosity and flow property called velocity.
CO 2: analyze the static stability of ship models.
CO 3: demonstrate the proof of Bernoulli theorem.
CO 4: measure the flow rate of liquids through pipes.
CO 5: measure the flow of water through canals.
drive.google.com/drive/folders/1weDZgt2NaJhKXQQHOLhFDwXr7hF6Rkf4