MECHANICAL Department


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Course Outcomes (CO's):

Course Name: Fluid Mechanics and Hydraulic Machines Course Outcomes (CO's):

  • Familiarize basic terms used in fluid mechanics
  • Understand the principles of fluid statics, kinematics and dynamics
  • Understand flow characteristics and classify the flows and estimate various losses in flow through channels
  • Analyze characteristics for uniform and non-uniform flows in open channels.
  • Design different types of turbines, centrifugal and multistage pumps.

Course Name: Manufacturing Process Course Outcomes (CO's):

At the end of the course, the student will be able to

  • Demonstrate different metal casting processes and gating systems. (L2)
  • Classify working of various welding processes. (L2)
  • Evaluate the forces and power requirements in rolling process. (L5)
  • Apply the principles of various forging operations. (L3)
  • Outline the manufacturing methods of plastics, ceramics and powder metallurgy. (L1)
  • Identify different unconventional processes and their applications. (L3)
Course Name: Thermodynamics Course Outcomes (CO's):

After completing the course, the student will be able to:

  • Understand the importance of thermodynamic properties related to conversion of heat energy into work. (L1)
  • Apply the laws of thermodynamics to boilers, heat pumps, refrigerators, heat engines, compressors and nozzles. (L3)
  • Utilize steam properties to design steam based components. (L4)
  • Analyze thermodynamic relations and air standard cycles. (L5)
Course Name: Mechanics of Materials Course Outcomes (CO's):
  • Evaluate stresses and strains
  • To draw the SF and BM diagrams for various beams under different loading conditions
  • Determine the resistance and deformation in machine members subjected to torsional loads and springs.
  • Analyze and design thin, thick cylinders.
  • Analysis of stresses in curved bars.
Course Name: Fluid mechanics & Hydraulic Machines LAB Course Outcomes (CO's):

By performing the various tests in this laboratory the student will be able to know the principles of discharge measuring devices and head loss due to sudden contraction and expansion in pipes and working principles of various pumps and motors.

Course Name: Manufacturing processes LAB Course Outcomes (CO's):

At the end of the lab, the student will be able to

  • Fabricate different types of components using various manufacturing techniques. (L6)
  • Adapt unconventional manufacturing methods. (L6)
Course Name: Mechanics of materials LAB Course Outcomes (CO's):
  • By performing the various tests in this laboratory the student will be able to know the structural behavior of various structural elements when subjected to external loads

Course Name: Applied Thermodynamics Course Outcomes (CO's):

  • After completing this course, the students can
  • Understand the working of IC engines with combustion process. (L1)
  • Select compressors for different applications. (L2)
  • Use T-s diagram in vapour power and gas power cycles. (L3)
  • Evaluate the relative performance of different steam turbines (L6)
  • Select appropriate refrigerant for different applications. (L6)
Course Name: Kinematics Of Machinery Course Outcomes (CO's):
  • Build up critical thinking and problem-solving capacity of various mechanical engineering problems related to kinematics of machines (L4)
  • Understand the basic principles of mechanisms in mechanical engineering (L1)
  • Assess various concepts of mechanisms like straight line motion mechanisms, Steering gear mechanisms and working principles of power elements (Gears, gear trains, Cams) and design related problems effectively (L6)
  • Examine the velocity and acceleration diagram for a given mechanism (L3)
  • Utilize analytical, mathematical and graphical aspects of kinematics of Machines for effective design (L3)
  • Construct the cam profile for a given motion (L3)
  • Analyze various gear trains (L4)
Course Name: Manufacturing Technology Course Outcomes (CO's):

At the end of the course, the student will be able to

  • Choose cutting processes and variables. (L3)
  • Relate tool wear and tool life. (L1)
  • Calculate the machining parameters for different machining processes. (L5)
  • Identify methods to generate different types of surfaces. (L3)
  • Explain work-holding requirements. (L2)
  • Design jigs and fixtures. (L6)
Course Name: Applied Thermodynamics LAB Course Outcomes (CO's):

Upon the successful completion of course, students will be able to

  • Explain different working cycles of engine
  • Describe various types of combustion chambers in IC engines
  • Illustrate the working of refrigeration and air conditioning systems
  • Evaluate heat balance sheet of IC engine
Course Name: Manufacturing Technology LAB Course Outcomes (CO's):
  • After completion of this course the student may be able to
  • Implement the concept of machining with various machine tools.(L5)
  • Get hands on experience on various machine tools and machining operations. (L5)
Course Name: Computer Aided Machine Drawing Course Outcomes (CO's):

After completion of this lab student will be able to

  • Demonstrate the conventional representations of materials and machine components.
  • Model riveted, welded and key joints using CAD system.
  • Create solid models and sectional views of machine components.
  • Generate solid models of machine parts and assemble them.
  • Translate 3D assemblies into 2D drawings.
  • Create manufacturing drawing with dimensional and geometric tolerances.

Course Name: CAD/CAM Course Outcomes (CO's):

    • Apply the basics of geometric representation and transformations in CAD/CAM. L3
    • Choose geometric modelling methods for building CAD models. L1
    • Compare NC, CNC and DNC. L2
    • Develop manual and computer aided part programming for turning and milling operations. L3
    • Summarize the principles of robotics AR, VR and AI in CIM.

Course Name: Design Of Machine Members Course Outcomes (CO's):

At the end of the course the students will be able to

  • Estimate safety factors of machine members subjected to static and dynamic loads. (L5)
  • Design fasteners subjected to variety of loads. (L6)
  • Selectof standard machine elements such as keys, shafts, couplings, springs and bearings. (L1)
  • Design clutches brakes and spur gears. (L6)
Course Name: Metrology& Measurements Course Outcomes (CO's):
  • List various measuring instruments used in metrology.
  • Examine geometry of screw threads and gear profiles.
  • Measure force, torque and pressure.
  • Calibrate various measuring instruments.

Course Name: Metrology& Measurements Lab Course Outcomes (CO's):

  • At the end of course the students will be able to:
  • Apply different instruments to measure length, width, depth, bore diameters, internal and external tapers, tool angles, and surface roughness.
  • Measure effective diameter of thread profile.
  • Conduct different machine alignment tests.
  • Measure temperature, displacement, and pressure.

Course Name: Computer Aided Modelling Lab Course Outcomes (CO's):

  • Students will be able to design different parts of mechanical equipment's
  • Students will be able to apply their skills in various designing and Manufacturing Industries.

Course Name: Dynamics Of Machinery Course Outcomes (CO's):

    • At the end of the course, the student will be able to
    • Determine the forces acting on various linkages when a mechanism is subjected to external forces.
    • Identify and correct the unbalances of rotating body
    • Analyze the vibratory motion of SDOF systems.
    • Reduce the magnitude of vibration and isolate vibration of dynamic systems
    • Determine dimensions of Governors for speed control.
Course Name: Finite Element Methods Course Outcomes (CO's):
    • Upon successful completion of this course you should be able to
    • Understand the concepts behind variational methods and weighted residual methods in FEM.
    • Identify the application and characteristics of FEA elements such as bars, beams, and isoparametric elements, and 3-D element.
    • Develop element characteristic equation procedure and generation of global stiffness equation will be applied.
    • Able to apply Suitable boundary conditions to a global structural equation, and reduce it to a solvable form.
    • Able to identify how the finite element method expands beyond the structural domain, for problems involving dynamics, heat transfer and fluid flow.

Course Name: Heat Transfer Course Outcomes (CO's):

    • Identify the application and characteristics of FEA elements such as bars, beams, and isoparametric elements, and 3-D element.
    • Develop element characteristic equation procedure and generation of global stiffness equation will be applied.
    • Able to apply Suitable boundary conditions to a global structural equation, and reduce it to a solvable form.
    • Able to identify how the finite element method expands beyond the structural domain, for problems involving dynamics, heat transfer and fluid flow.

Course Name: Computer Aided Design LAB Course Outcomes (CO's):

    • Ability to solve engineering problems using the commercial software's such as ANSYS,
    • SIMUFACT, ABAQUS, SIMULIA, Mathematical, MAT LAB, GNU Octave, Scilab, MAPLE/ COMSOL.
Course Name: Computer Aided Manufacturing LAB Course Outcomes (CO's):
    • Upon successful completion students should be able to:
    • Use and understanding of Preparatory and Miscellaneous (G& M) codes to generate or edit a program which will operate a CNC Lathe/ Milling and Drilling.
    • Apply mathematical methods to calculate World/ Joint/ Tool coordinates in robotics.
    • Apply the programming concepts of Robots for simple applications in material handling and assembly

Course Name: Heat Transfer LAB Course Outcomes (CO's):

Upon the successful completion of course, students will be able to

  • Explain different modes of heat transfer
  • Identify parameters for measurement for calculating heat transfer
  • Determine effectiveness of heat exchanger
  • Design new equipment related to heat transfer
  • Apply principles of heat transfer in wide application in industries.