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B.L.D.E.Association’sVachana Pitamaha Dr. P.G. Halakatti College of Engineering & Technology, Bijapur.
Course Outcomes
Department: Mechanical Engineering Program: BE in Mechanical Engineering
List of Program Outcomes (POs)Engineering Graduates will be able to:1. Engineering knowledge: Apply the knowledge of mathematics, science, engineering fundamentals, and an engineering specialization to the solution of complex engineeringproblems.2. Problem analysis: Identify, formulate, review research literature, and analyze complexengineering problems reaching substantiated conclusions using first principles of mathematics, natural sciences, and engineering sciences.
3. Design/development of solutions: Design solutions for complex engineering problems and design system components or processes that meetthe specified needs with appropriate consideration for the public health and safety, and the cultural, societal, and environmentalconsiderations.
4. Conduct investigations of complex problems: Use research-based knowledge and researchmethods including design of experiments, analysis and interpretation of data, and synthesis of the information to provide valid conclusions.
5. Modern tool usage: Create, select, and apply appropriate techniques, resources, and modernengineering and IT tools including prediction and modeling to complex engineering activities with an understanding of the limitations.
6. The engineer and society: Apply reasoning informed by the contextual knowledge to assess societal, health, safety, legal and cultural issues and the consequent responsibilities relevant tothe professional engineering practice.
7. Environment and sustainability: Understand the impact of the professional engineering solutions in societal and environmental contexts, and demonstrate the knowledge of, and needfor sustainable development.
8. Ethics: Apply ethical principles and commit to professional ethics and responsibilities andnorms of the engineering practice.
9. Individual and team work: Function effectively as an individual, and as a member or leaderin diverse teams, and in multidisciplinary settings.
10. Communication: Communicate effectively on complex engineering activities with the engineering community and with society at large, such as, being able to comprehend and write effective reports and design documentation, make effective presentations, and give andreceive clear instructions.
11. Project management and finance: Demonstrate knowledge and understanding of theengineering and management principles and apply these to one’s own work, as a member and leader in a team, to manage projects and in multidisciplinary environments.
12. Life-long learning: Recognize the need for and have the preparation and ability to engage inindependent and life-long learning in the broadest context of technological change.
B.L.D.E.Association’sVachana Pitamaha Dr. P.G. Halakatti College of Engineering & Technology, Bijapur.
Program Specific OutcomesDepartment: Mechanical Engineering Program: BE in Mechanical Engineering
List of Program Specific Outcomes (PSO)
The mechanical engineering graduates will be able to;
1 .Apply the Mechanical Engineering concepts to model, design, analyze and realize mechanical systems, components or processes.
2.Use modern CAE tools to solve Mechanical Engineering problems
3. Prepare and present projects reports effectively.
B.L.D.E.Association’s
Vachana Pitamaha Dr. P.G. Halakatti College of Engineering & Technology, Bijapur.Course Outcomes
Department: Mechanical Engineering Program: BE in Mechanical Engineering
Subject CodeCourse
OutcomesStatement
III Semester
1. TRANSFORM CALCULUS, FOURIER SERIES ANDNUMERICAL TECHNIQUES
18MAT31
C01Use Laplace transform and inverse Laplace transform in solving differential/ integral equationarising in network analysis, control systems and other fields of engineering.
CO2Demonstrate Fourier series to study the behaviour of periodic functions and their applications insystem communications, digital signal processing and field theory.
CO3Make use of Fourier transform and Z-transform to illustrate discrete/continuous function arisingin wave and heat propagation, signals and systems.
CO4Solve first and second order ordinary differential equations arising in engineering problemsusing single step and multistep numerical methods.
CO5Determine the externals of functional using calculus of variations and solve problems arisingin dynamics of rigid bodies and vibrational analysis.
2. MECHANICS OF MATERIALS
18ME32
C01 Understand simple, compound, thermal stresses and strains their relations and strain energy.
CO2 Analyse structural members for stresses, strains and deformations.
CO3 Analyse the structural members subjected to bending and shear loads.
CO4 Analyse shafts subjected to twisting loads.
CO5 Analyse the short columns for stability.
Subject CodeCourse
OutcomesStatement
3. BASICTHERMODYNAMICS
18ME33
C01Explain fundamentals of thermodynamics and evaluate energy interactions across the boundary of thermodynamic systems.
CO2Evaluate the feasibility of cyclic and non-cyclic processes using 2nd law of thermodynamics.
CO3Apply the knowledge of entropy, reversibility and irreversibility to solve numerical problems and apply 1st law of thermodynamics to closed and open systems and determine quantity of energy transfers and change in properties.
CO4Interpret the behavior of pure substances and its application in practical problems.
CO5Recognize differences between ideal and real gases and evaluate thermodynamic properties of ideal and real gas mixtures using various relations.
4. MATERIAL SCIENCE
18ME34
C01Understand the mechanical properties of metals and their alloys.
CO2Analyze the various modes of failure and understand the microstructures of ferrous and nonferrous materials.
CO3Describe the processes of heat treatment of various alloys.
CO4Acquire the Knowledge of composite materials and their production process as well as applications.
CO5Understand the properties and potentialities of various materials available and material selection procedures.
SubjectCode
CourseOutcomes
Statement
5. METALCASTING AND
WELDING
18ME35A
C01 Describe the casting process and prepare different types of cast products.
CO2 Acquire knowledge on Pattern, Core, Gating, Riser system and to use Jolt, Squeeze, Sand Slinger moulding machinesCO3 Compare the Gas fired pit, Resistance, Coreless, Electrical and Cupola Metal FurnacesCO4 Compare the Gravity, Pressure die, Centrifugal, Squeeze, slush and Continuous Metal mold castings.CO5 Understand the Solidification process and Casting of Non-Ferrous Metals.CO6 Describe the Metal Arc, TIG, MIG, Submerged and Atomic Hydrogen Welding processes etc. used in manufacturingCO7 Describe methods for the quality assurance of components made of casting and joining process
6.MECHANICAL
MEASUREMENTAND
METROLOGY
18ME36B
C01 Understand the objectives of metrology, methods of measurement, standards of measurement & various measurement parameters.
CO2Explain tolerance, limits of size, fits, geometric and position tolerances, gauges and their design and also understand the working principle of different types of comparators.
CO3Describe measurement of major & minor diameter, pitch, angle and effective diameter of screw threads & understand advanced metrology concepts.
CO4 Explain measurement systems, transducers, intermediate modifying devices and terminating devices
CO5Describe functioning of force, torque, pressure, strain and temperature measuring devices.
7. METALCUTTING AND
FORMING
18ME35B
C01 Explain the construction & specification of various machine tools.
CO2 Discuss different cutting tool materials, tool nomenclature & surface finish.CO3 Apply mechanics of machining process to evaluate machining time.CO4 Analyze tool wear mechanisms and equations to enhance tool life and minimize machining cost.CO5 Understand the concepts of different metal forming processes.CO6 Apply the concepts of design of sheet metal dies to design different dies for simple sheet metal components.
Subject CodeCourse
OutcomesStatement
8. CAMD18ME36A
C01 Identify the national and international standards pertaining to machine drawing.
CO2 Understand the importance of the linking functional and visualization aspects in the preparation of the part drawings
CO3 Apply limits and tolerances to assemblies and choose appropriate fits for given assemblies
CO4 Interpret the Machining and surface finish symbols on the component drawings.
CO5 Preparation of the part or assembly drawings as per the conventions.
9. MECHANICALMEASUREMENT AND
METROLOGYLAB(MMM)
18MEL37 B
C01 To calibrate pressure gauge, thermocouple, LVDT, load cell, micrometer.CO2 To measure angle using Sine Centre/ Sine Bar/ Bevel Protractor, alignment using Autocollimator/ Roller set.
CO3 To demonstrate measurements using Optical Projector/Tool maker microscope, Optical flats.
CO4 To measure cutting tool forces using Lathe/Drill tool dynamometer.
CO5To measure Screw thread parameters using 2-Wire or 3-Wire method, gear tooth profile using gear tooth Vernier/Gear tooth micrometer
CO6 To measure surface roughness using Tally Surf/ Mechanical Comparator.
FOUNDRY FORGING&WELDING LAB(F&F
LAB)18MEL38 B
C01Demonstrate various skills in preparation of molding sand for conducting tensile, shear and compression tests using Universal sand testing machine.
CO2Demonstrate skills in determining permeability, clay content and Grain Fineness Number of base sands.
CO3Demonstrate skills in preparation of forging models involving upsetting, drawing and bending operations.
CO4 Demonstrate skills in preparation of various welding joints on M.S flats using Arc welding equipment
11.MATERIAL TESTING 18MEL37 A C01 Acquire experimentation skills in the field of material testing.
Subject CodeCourse
OutcomesStatement
LAB(MT LAB)
CO2 Develop theoretical understanding of the mechanical properties of materials by performing experiments.
CO3 Apply the knowledge to analyze a material failure and determine the failure inducing agent/s.
CO4 Apply the knowledge of testing methods in related areas.
CO5 Understand how to improve structure/behavior of materials for various industrial applications.
12. WORK SHOP ANDMACHINE SHOPPRACTICE(W/S)
18MEL38 A
C01To read working drawings, understand operational symbols and execute machining operations.
CO2 Prepare fitting models according to drawings using hand tools- V-block, marking gauge, files, hack saw, drills etc.
CO3Understand integral parts of lathe, shaping and milling machines and various accessories and attachments used thereof.
CO4 Select cutting parameters like cutting speed, feed, depth of cut, and tooling for various machining operations.
CO5Perform cylindrical turning operations such as plain turning, taper turning, step turning, thread Cutting, facing, knurling,internal thread cutting, eccentric turning and estimate cutting time.
CO6Perform machining operations such as plain shaping, inclined shaping, keyway cutting, Indexing and Gear cutting and estimate cutting time.
13. ADVANCEDMATHEMATICS
18MATDIP31
C01Apply concepts of complex numbers and vector algebra to analyze the problems arising inrelated area.
CO2 Use derivatives and partial derivatives to calculate rate of change of multivariate functions.
CO3Analyze position, velocity and acceleration in two and three dimensions of vector valuedfunctions.
CO4 Learn techniques of integration including the evaluation of double and triple integrals.
CO5 Identify and solve first order ordinary differential equations.
B.L.D.E.Association’sVachana Pitamaha Dr. P.G. Halakatti College of Engineering & Technology, Bijapur.
Course Outcomes
Department: Mechanical Engineering Program: BE in Mechanical Engineering
Subject CodeCourse
OutcomesStatement
IV Semester
1. COMPLEX ANALYSIS,PROBABILITY AND
STATISTICAL METHODS 18MAT41
C01Use the concepts of analytic function and complex potentials to solve the problems arising inelectromagnetic field theory.
CO2Utilize conformal transformation and complex integral arising in aerofoil theory, fluid flowvisualization and image processing.
CO3Apply discrete and continuous probability distributions in analyzing the probability modelsarising in engineering field.
CO4Make use of the correlation and regression analysis to fit a suitable mathematical model for thestatistical data.
CO5 Construct joint probability distributions and demonstrate the validity of testing the hypothesis.
APPLIEDTHERMODYNAMICS
18ME42
C01 Apply thermodynamic concepts to analyze the performance of gas power cycles.
CO2 Apply thermodynamic concepts to analyze the performance of vapour power cycles.
CO3Understand combustion of fuels and performance of I C engines. • Understand the principles and applications of refrigeration systems.
CO4 Apply Thermodynamic concepts to determine performance parameters of refrigeration and airconditioning systems.
CO5Understand the working principle of Air compressors and Steam nozzles, applications, relevance of air and identify methods for performance improvement.
Subject CodeCourse
OutcomesStatement
Fluid Mechanics 18 ME43
C01Identify and calculate the key fluid properties used in the analysis of fluid behavior.
CO2 Explain the principles of pressure, buoyancy and floatation
CO3Apply the knowledge of fluid statics, kinematics and dynamics while addressing problems of mechanical and chemical engineering
CO4 Describe the principles of fluid kinematics and dynamics.
CO5Explain the concept of boundary layer in fluid flow and apply dimensional analysis to form dimensionless numbers in termsof input output variables.
CO6 Illustrate and explain the basic concept of compressible flow and CFD
Kinematics of Machines 18ME44
C01 Knowledge of mechanisms and their motion..
C02 Understand the inversions of a four bar mechanisms
C03 Analyse the velocity, acceleration of links and joints of mechanisms.
C04 Analysis of cam follower motion for the motion specifications.
C05 Understand the working of the spur gears & Analyse the gear trains speed ratio and torque.
B.L.D.E.Association’sVachana Pitamaha Dr. P.G. Halakatti College of Engineering & Technology, Bijapur.
Course Outcomes
Department: Mechanical Engineering Program: BE in Mechanical Engineering
V Semester
SubjectCode
CourseOutcomes
Statement
MANAGEMENTAND
ECONOMICS18ME51
C01Understand needs, functions, roles, scope and evolution of Management
CO2Understand importance, purpose of Planning and hierarchy of planning and also analyzeits types.
CO3Discuss Decision making, Organizing, Staffing, Directing and Controlling.
CO4Select the best economic model from various available alternatives.
CO5Understand various interest rate methods and implement the suitable one.
CO6Estimate various depreciation values of commodities
CO7Prepare the project reports effectively.
Subject CodeCourse
OutcomesStatement
DESIGN OF MACHINEELEMENTS I
18ME 52
CO1Apply the concepts of selection of materials for given mechanical components.
CO2List the functions and uses of machine elements used in mechanical systems.
CO3Apply codes and standards in the design of machine elements and select an elementbased on the manufacturer’s catalog.
CO4Analyze the performance and failure modes of mechanical components subjected tocombined loading and fatigue loading using the concepts of theories of failure.
CO5Demonstrate the application of engineering design tools to the design of machinecomponents like shafts, couplings, power screws, fasteners, welded and riveted joints.
CO6 Understand the art of working in a team.
Subject CodeCourse
OutcomesStatement
DYNAMICS OF MACHINES 18ME53
CO1Analyse the mechanisms for static and dynamic equilibrium.
CO2Carry out the balancing of rotating and reciprocating masses
CO3Analyse different types of governors used in real life situation.
CO4Analyse the gyroscopic effects on disks, airplanes, stability of ships, two and fourwheelers
CO5Understand the free and forced vibration phenomenon.
CO6 Determine the natural frequency, force and motion transmitted in vibrating systems.
Subject CodeCourse
OutcomesStatement
TURBO MACHINES 18ME54
C01Model studies and thermodynamics analysis of turbomachines
CO2Analyse the energy transfer in Turbo machine with degree of reaction and utilisation factor
CO3Classify, analyse and understand various type of steam turbine.
CO4Classify, analyse and understand various type of hydraulic turbine.
CO5 Understand the concept of radial power absorbing machine and the problems involved duringits operation.
FLUID POWER ENGINEERING
18ME55
C01Identify and analyse the functional requirements of a fluid power transmission system for a givenapplication.
CO2 Visualize how a hydraulic/pneumatic circuit will work to accomplish the function.
CO3Design an appropriate hydraulic or pneumatic circuit or combination circuit like electrohydraulics,electro-pneumatics for a given application.
CO4 Select and size the different components of the circuit.
CO5Develop a comprehensive circuit diagram by integrating the components selected for the givenapplication.
Subject CodeCourse
OutcomesStatement
OPERATIONSMANAGEMENT
18ME56
C01 Explain the concept and scope of operations management in a busines s context
CO2Recognize the role of Operations management among various busines2s functions and its rolein the organizations’ strategic planning and gaining competitive advantage.
CO3Analyze the appropriateness and applicability of a range of op3e rations managementsystems/models in decision making.
CO4Assess a range of strategies for improving the efficiency and effective4n ess of organizationaloperations.
CO5 Evaluate a selection of frameworks used in the design and delivery of 5o perations
FLUID MECHANICS ANDMACHINERY LAB
18MEL57
C01 Perform experiments to determine the coefficient of discharge of flow measuring devices.
CO2 Conduct experiments on hydraulic turbines and pumps to draw characteristics.
CO3Test basic performance parameters of hydraulic turbines and pumps and execute theknowledge in real life situations.
CO4 Determine the energy flow pattern through the hydraulic turbines and pumps
CO5 Exhibit his competency towards preventive maintenance of hydraulic machines
Subject CodeCourse
OutcomesStatement
ENERGY CONVERSIONLAB
18MEL58
C01 Perform experiments to determine the properties of fuels and oils.
CO2 Conduct experiments on engines and draw characteristics.
CO3Test basic performance parameters of I.C. Engine and implement the knowledge inindustry.
CO4Identify exhaust emission, factors affecting them and exhibit his competency towardspreventive maintenance of IC engines.
B.L.D.E.Association’sVachana Pitamaha Dr. P.G. Halakatti College of Engineering & Technology, Bijapur.
Course Outcomes
Department: Mechanical Engineering Program: BE in Mechanical Engineering
VI SEMESTER
SubjectCode
CourseOutcomes
Statement
FINITEELEMENTMETHODS
18ME61
C01Identify the application and characteristics of FEA elements such as bars, beams, plane andiso-parametric elements.
C02 Develop element characteristic equation and generation of global equation.C03 Formulate and solve Axi-symmetric and heat transfer problems.
C04Apply suitable boundary conditions to a global equation for bars, trusses, beams, circularshafts, heat transfer, fluid flow, axi-symmetric and dynamic problems.
DESIGN OFMACHINE
ELEMENTS II18ME62
C01Apply design principles for the design of mechanical systems involving springs, belts,pulleys, and wire ropes.
C02Design different types of gears and simple gear boxes for relevant applications.
C03Understand the design principles of brakes and clutches.
C04Apply design concepts of hydrodynamic bearings for different applications and selectAnti friction bearings for different applications using the manufacturers, catalogue.
C05Apply engineering design tools to product design.
CO6 Become good design engineers through learning the art of working in a team.
SubjectCode
CourseOutcomes
Statement
HEAT TRANSFER
18ME63
C01Understand the modes of heat transfer and apply the basic laws to formulate engineering systems.
C02Understand and apply the basic laws of heat transfer to extended surface, composite material andunsteady state heat transfer problems.
C03Analyze heat conduction through numerical methods and apply the fundamental principle to solveradiation heat transfer problems.
C04Analyze heat transfer due to free and forced convective heat transfer.
C05Understand the design and performance analysis of heat exchangers and their practical applications,Condensation and Boiling phenomena.
PROFESSIONAL ELECTIVE 1
18ME641
C011. Understand the compare traditional and non-traditional machining process and recognize the need forNon-traditional machining process.
C02. Understand the constructional features, performance parameters, process characteristics, applications,advantages and limitations of USM, AJM and WJM.
C03Identify the need of Chemical and electro-chemical machining process along with the constructionalfeatures, process parameters, process characteristics, applications, advantages and limitations.
C04. Understand the constructional feature of the equipment, process parameters, process characteristics,applications, advantages and limitations EDM & PAM.
CO5. Understand the LBM equipment, LBM parameters, and characteristics. EBM equipment and mechanism ofmetal removal, applications, advantages and limitations LBM & EBM.
Subject CodeCourse
OutcomesStatement
REFRIGERATION AND AIR CONDITIONING
18ME642
C01Illustrate the principles, nomenclature and applications of refrigeration systems.
CO2Explain vapour compression refrigeration system and identify methods for performanceimprovement
CO3Study the working principles of air, vapour absorption, thermoelectric and steam-jet andthermoacoustic refrigeration systems.
CO4Estimate the performance of air-conditioning systems using the principles of psychrometry.
CO5Compute and Interpret cooling and heating loads in an air-conditioning system.
CO6 Identify suitable refrigerant for various refrigerating systems.
Subject CodeCourse
OutcomesStatement
THEORY OF ELASTICITY 18ME643
C01
Understand the Basic field equations of linear elastic solids, force, stress, strain andequilibrium in solids.
CO2Analyse the 2D structural elements, beams, cylinders.
CO3Use analytical techniques to predict deformation, internal force and failure of simple solidsand structural components
CO4Analyse the axisymmetric structural elements.
CO5Analyse the structural members subjected to torsion
CO6 Determine the thermal stresses in plain stress and plane stain conditions.
ADVANCED VIBRATIONS 18ME644
C01Characterize the single and multi degrees of freedom systems subjected to free and forcedvibrations with and without damping.
CO2 Apply the method of vibration measurements and its controlling.
CO3Determine vibratory responses of SDOF and MDOF systems to harmonic, periodic and nonperiodicexcitation
CO4 Analyze the mathematical model of a linear vibratory system to determine its response
CO5 Obtain linear mathematical models of real life engineering systems
CO6 Use the concept of dynamic vibrations for a continuous system.
Subject CodeCourse
OutcomesStatement
COMPOSITE MATERIALSTECHNOLOGY
18ME645
C01Use different types of manufacturing processes in the preparation of composite materials
CO2Analyze the problems on macro mechanical behaviour of composites
CO3Analyze the problems on micromechanical behaviour of Composites
CO4Determine stresses and strains relation in composites materials.
CO5Understand and effective use of properties in design of composite structures
CO6 Perform literature search on a selected advanced material topic
Subject CodeCourse
OutcomesStatement
COMPUTER AIDEDMODELLING AND
ANALYSIS LAB15MEL66
C01
Use the modern tools to formulate the problem, create geometry, descritize, apply boundaryconditions to solve problems of bars, truss, beams, and plate to find stresses with different-loadingconditions.
CO2
Demonstrate the ability to obtain deflection of beams subjected to point, uniformly distributed andvarying loads and further to use the available results to draw shear force and bending momentdiagrams.
CO3Analyze and solve 1D and 2D heat transfer conduction and convection problems with differentboundary conditions.
CO4
Carry out dynamic analysis and finding natural frequencies of beams, plates, and bars for variousboundary conditions and also carry out dynamic analysis with forcing functions and analyze theresults.
HEAT TRANSFER LAB 18MEL67
C01Determine the thermal conductivity of a metal rod and overall heat transfercoefficient of composite slabs.
CO2 Determine convective heat transfer coefficient for free and forced convectionand correlate with theoretical values.
CO3Evaluate temperature distribution characteristics of steady and transient heatconduction through solid cylinder experimentally.
CO4Determine surface emissivity of a test plate and Stefan Boltzmann constant
CO5Estimate performance of a refrigerator and effectiveness of a fin and Doublepipe heat exchanger
NON-CONVENTIONALENERGY SOURCES
18ME651
C01
Describe the environmental aspects of non-conventional energy resources. InComparison with various conventional energy systems, their prospects andlimitations.
CO2Know the need of renewable energy resources, historical and latest developments.
CO3
Describe the use of solar energy and the various components used in the energyproduction with respect to applications like-heating, cooling, desalination, powergeneration, drying, cooking etc.
CO4Appreciate the need of Wind Energy and the various components used in energygeneration and know the classifications.
CO5Understand the concept of Biomass energy resources and their classification, typesof biogas Plants-applications
CO6Compare Solar, Wind and bio energy systems, their prospects, Advantages andlimitations.
CO7Acquire the knowledge of fuel cells, wave power, tidal power and geothermalprinciples and applications.
VII SEMESTER
SubjectCode
CourseOutcome
s
Statement
CONTROLENGINEERING
18ME71
C01 Identify the type of control and control actions.CO2 Develop the mathematical model of the physical systems.CO3 Estimate the response and error in response of first and second order systems subjected standard input signals.CO4 Represent the complex physical system using block diagram and signal flow graph and obtain transfer function.
CO5Analyse a linear feedback control system for stability using Hurwitz criterion, Routh’s criterion and root Locus technique in complex domain.
CO6Analyse the stability of linear feedback control systems in frequency domain using polar plots, Nyquist and Bodeplots.
COMPUTERINTEGRATED DESIGN
AND MANUFACTURING
18ME72
C01To impart knowledge of CIM and Automation and different concepts of automation by developing mathematical models.
CO2To make students to understand the Computer Applications in Design and Manufacturing [CAD / CAM) leading to Computer integrated systems. Enable them to perform various transformations of entities on display devices.
CO3To expose students to automated flow lines, assembly lines, Line Balancing Techniques, and Flexible Manufacturing Systems.
CO4 To expose students to computer aided process planning, material requirement planning, capacity planning etc
CO5 To expose the students to CNC Machine Tools, CNC part programming, and industrial robots.
CO6To introduce the students to concepts of Additive Manufacturing, Internet of Things, and Industry 4.0 leading to Smart Factory.
Subject CodeCourse
OutcomesStatement
TOTAL QUALITYMANAGEMENT
18ME734
C01 Explain the various approaches of TQM
CO2 Infer the customer perception of quality
CO3 Analyze customer needs and perceptions to design feedback systems..
CO4 Apply statistical tools for continuous improvement of systems
CO5 Apply the tools and technique for effective implementation of TQM.
TRIBOLOGY 18ME822
C01 Understand the fundamentals of tribology and associated parameters.
CO2 Apply concepts of tribology for the performance analysis and design of components experiencing relative motion.
CO3 Analyse the requirements and design hydrodynamic journal and plane slider bearings for a given application
CO4 Select proper bearing materials and lubricants for a given tribological application.
CO5 Apply the principles of surface engineering for different applications of tribology
Subject CodeCourse
OutcomesStatement
SUPPLY CHAIN MANAGEMENT 18ME653
C01 Understand the framework and scope of supply chain management.
CO2 Build and manage a competitive supply chain using strategies, models, techniques and information technology.
CO3 Plan the demand, inventory and supply and optimize supply chain network.
CO4 Understand the emerging trends and impact of IT on Supply chain.
COMPTER INTEGRATEDMAUFACTURING LAB
18MEL76
C01Understand CNC Lathe part programming techniques for Turning, Facing, Chamfering, Grooving, Step turning, Taperturning, Circular interpolation etc.
C02Generate CNC Mill Part programming for Point to point motions, Line motions, Circular interpolation, Contour motion, Pocket milling- circular, rectangular, Mirror commands etc.
C03 Apply Canned Cycles for Drilling, Peck drilling, Boring, Tapping, Turning, Facing, Taper turning Thread cutting etc.
C04Apply simulation techniques for Tool Path generation for different machining operations of small components using CNC Lathe & CNC Milling Machine.
C05Apply high end CAM packages for machining complex parts; use state of art cutting tools and related cutting parameters and optimize cycle time.
C06Understand & write programs for Robot control; understand the operating principles of hydraulics, pneumatics and electro pneumatic systems.
Subject CodeCourse
OutcomesStatement
Design Laboratory 18MEL77
C01Compute the natural frequency of the free and forced vibration of single degree freedom systems, critical speed of shafts.
C02 Carry out balancing of rotating masses.
C03 Analyse the governor characteristics.
C04 Determine stresses in disk, beams, plates and hook using photo elastic bench.
C05 Determination of Pressure distribution in Journal bearing
C06Analyse the stress and strains using strain gauges in compression and bending test and stress distribution in curved beams.
PROJECT WORK PHASE - 1 18MEP78
C01Undertake problem, identification, formulation and solution.
C02Design and develop a functional product prototype while working in a team.
C03Use fundamental knowledge and skills in mechanical engineering and supply it effectively on a project to solve contemporary issues
Subject CodeCourse
OutcomesStatement
INTERNSHIP INT
C01Understand the process of applying the engineering knowledge to solve industrial problems.
C02Applying to demonstrate the impact of internship on their learning and professional development.
C03Understanding of lifelong learning processes to critical reflection of internship experiences.
B.L.D.E.Association’sVachana Pitamaha Dr. P.G. Halakatti College of Engineering & Technology, Bijapur.
Course Outcomes
Department: Mechanical Engineering Program: BE in Mechanical Engineering
VIII SEMESTER
Subject CodeCourse
OutcomesStatement
ENERGY ENGINEERING 18ME81
C01 Understand the construction and working of steam generators and their accessories.
C02 Identify renewable energy sources and their utilization.
C03Understand principles of energy conversion from alternate sources including wind, geothermal, ocean, biomass, nuclear, hydel and tidal.
MECHATRONICS 18ME744
C01 Illustrate various components of Mechatronics systems.
C02 Assess various control systems used in automation.
C03 Develop mechanical, hydraulic, pneumatic and electrical control systems.
C04Design and conduct experiments to evaluate the performance of a mechatronics system or component with respect to specifications, as well as to analyze and interpret data.
C05 Function effectively as members of multidisciplinary teams.
Subject CodeCourse
OutcomesStatement
PROJECT WORK PHASE - 2 18MEP83
C01
C02
C03
SEMINAR 18MES84
C01
C02
C03
Subject CodeCourse
OutcomesStatement
INTERNSHIP 18MEI85
C01
C02
C03
C04
C05
C06
B.L.D.E.Association’s
Vachana Pitamaha Dr. P.G. Halakatti College of Engineering & Technology, Bijapur.Course Outcomes
Department: Mechanical Engineering Program: M.Tech in Machine design
Programme Outcomes (POs)1) A post graduate of the Computer Science and Engineering Program will demonstrate:Scholarship of Knowledge : Acquire in-depth knowledge of computer science and engineering, including wider and global perspective,with an ability to discriminate, evaluate, analyze and synthesize existing and new knowledge, and integration of the same forenhancement of knowledge.2) Critical Thinking : Analyze complex computer science and engineering problems critically, apply independent judgment forsynthesizing information to make intellectual and/or creative advances for conducting research in a wider theoretical, practical andpolicy context.3) Problem Solving :Think laterally and originally, conceptualize and solve computer science and engineering problems, evaluate a widerange of potential solutions for those problems and arrive at feasible, optimal solutions after considering public health and safety,cultural, societal and environmental factors in the core areas of expertise.
4) Research Skill : Extract information pertinent to unfamiliar problems through literature survey and experiments, apply appropriateresearch methodologies, techniques and tools, design, conduct experiments, analyze and interpret data, demonstrate higher order skilland view things in a broader perspective, contribute individually/in group(s) to the development of scientific/technological knowledgein one or more domains of computer science and engineering.
5) Usage of modern tools: Create, select, learn and apply appropriate techniques, resources, and modern engineering and IT and ICTtools, including prediction and modeling, to complex computer science and engineering activities with an understanding of thelimitations.
6)Collaborative and Multidisciplinary work: Possess knowledge and understanding of group dynamics, recognize opportunities andcontribute positively to collaborative-multidisciplinary scientific research, demonstrate a capacity for self-management and teamwork,decision-making based on open-mindedness, objectivity and rational analysis in order to achieve common goals and further thelearning of themselves as well as others.7) Project Management and Finance: Demonstrate knowledge and understanding of computer science and engineering and management
principles and apply the same to one’s own work, as a member and leader in a team, manage projects efficiently in computer scienceand disciplines and multidisciplinary environments after consideration of economical and financial factors.8) Communication :Communicate with the engineering community, and with society at large, regarding complex computer science andengineering activities confidently and effectively, such as, being able to comprehend and write effective reports and designdocumentation by adhering to appropriate standards, make effective presentations, and give and receive clear instructions.9) Life-long Learning : Recognize the need for, and have the preparation and ability to engage in life-long learning independently,with a high level of enthusiasm and commitment to improve knowledge and competence continuously in computer science andengineering.10) Ethical Practices and Social Responsibility: Acquire professional and intellectual integrity, professional code of conduct, ethics ofresearch and scholarship, consideration of the impact of research outcomes on professional practices and an understanding ofresponsibility to contribute to the community for sustainable development of society.11) Independent and Reflective Learning: Observe and examine critically the outcomes of one’s actions and make corrective measuressubsequently, and learn from mistakes without depending on external feedback.
I SEMESTER
Subject CodeCourse
OutcomesStatement
ADVANCED THEORY OFVIBRATIONS
18MDE12
CO1Apply Newtons equation of motion and energy methods to model basic vibratingmechanical system, model undamped and damped mechanical systems andstructures for free and harmonically forced vibrations.
CO2Model single-and multi-degree of freedom for free and forced vibrations anddetermine response to vibration, natural frequencies and modes of vibration
CO3 Apply the fundamentals of vibration to its measurement and analysis
CO4Solve realistic vibration problems in mechanical engineering design that involvesapplication of most of the course syllabus.
CONTINUUMMECHANICS
18MDE13
CO1 Treat general stresses and deformations in continuous materials
CO2Formulate and solve specific technical problems of displacement, strain andstress.
CO3 Perform experiments with stresses and deformations
CO4Model and analyse the stresses and deformations of simple geometries under anarbitrary load in solids.
DYNAMICS ANDMECHANISM DESIGN
18MDE14
CO1To provide a theoretical and practical foundation for analysis and design of articulatedmechanical systems for desired applications.
CO2 evelop skills to analyze the displacement, velocity, and acceleration of mechanisms.
CO3 Improve understanding of the synthesis of mechanismsfor given tasks
CO4To includedynamics considerations in thedesignofmechanismsforengineeringapplications.
FRACTURE MECHANICS 18MDE15
CO1Develop basic fundamental understanding of the effects of crack like defectson the performance of aerospace, civil, and mechanical engineeringstructures.
CO2Be able to select appropriate materials for engineering structures to insuredamage tolerance.
CO3Learn to employ modern numerical methods to determine critical crack sizesand fatigue crack propagation rates in engineering structures.
CO4Understand the relationship between crack tip opening displacement, SIF andERR and application of such parameters for ductile and brittle materials.
CO5Understanding of experimental techniques to determine the critical values ofparameters at crack tip.
CO6Understand and appreciate of the status of academic research in field offracture mechanics.
II SEMESTER
FINITE ELEMENTMETHOD
18MEA21
CO1Understand the concepts of Variational methods and Weighted residualmethods.
CO2Identify the application and characteristics of FEA elements such as bars,beams, plane and isoparametric elements, and 3D element.
CO3Develop element characteristic equations and generate global stiffnessequations.
CO4Apply suitable boundary conditions to a global structural equation, andreduce it to a solvable form.
CO5Identify how the finite element method expands beyond the structuraldomain, for problems involving dynamics and heat transfer.
ADVANCED MACHINEDESIGN
18MDE22CO1
Apply stateofthe art design methodologynamelydesign byanalysisanddamagetolerant design to mechanical components.
CO2 Distinguish different design criteria and their procedure to carry out the design of
mechanical components.
CO3 Design machine components which are subjected to fluctuating loads.
CO4Design machine components using techniques like stress life approach, Strain lifeapproach and Fracture mechanics approach.
CO5Define the various statistical aspects of fatigue using different probabilitydistribution plots.
CO6Explain the contact stresses and implementation of Hertz contactphenomenon to the real field problem.
CO7 Explain surface failure mechanisms.
TRIBOLOGY ANDBEARING DESIGN
18MDE23
CO1Design or choose efficient tribological systems such as rolling element bearings,hydrodynamic bearings, and dry sliding bearings, for the needs of a specificapplication.
CO2 Select compatible materials for minimizing friction and wear in machinery
CO3Explain the concepts advanced bearings like magnetic bearings, porous bearingsand gas lubricated bearings.
MATERIAL HANDLINGEQUIPMENT DESIGN
18MDE241
CO1Select appropriate equipment for material handling and understand the basicroles of the different equipment.
CO2Apply appropriate techniques for improving existing material handling systems;recognize the importance of safety and applicatons of optimization techniquesto material handling.
COMPUTERAPPLICATIONS IN DESIGN
18MEA242
CO1D evelop expertise in generation of various curves, surfaces and volumes usedin geometric modeling systems.
CO2Design, implement, and evaluate a computer-based system, process,component, or program to meet desired needs.
CO3Analyze a problem, and identify and define the computing requirementsappropriate to its solution.
ROTOR DYNAMICS 18MDE243
CO1Provides the student understanding of modeling rotating machine elementstheoretically.
CO2Upon completion of this course, students will have gained anunderstanding of the design, application, and reliability evaluation ofbearings in rotating machinery applications.
DESIGN OPTIMIZATION 18CAE251
CO1 Identify and apply relevant problem solving methodologies.
CO2Design components, systems and/ or processes to meet requiredspecification.
CO3 Optimizeanexistingdesignwithsingleormultipleobjectivefunctions.
CO4Apply decision-making methodologies to evaluate solutions for efficiency,effectiveness and sustainability.
AUTOMOBILESYSTEMDESIGN
18MEA252
CO1Gain an insight into aspects of vehicle design, operation and maintenance,which will be useful for taking up a position in the automotive industry.
CO2Applytheknowledgeincreatingapreliminarydesign of automobilesubsystems.
CO3Identify construction, working, preventive maintenance, trouble shootingand diagnosis of various Automobile Systems.
CO4Identify Modern technology and safety measures used in AutomotiveVehicles.
COMPUTATIONAL FLUIDDYNAMICS
18MEA253CO1
Understand the process of developing a geometrical model of the flow,applying appropriate boundary conditions, specifying solutionparameters, and visualising and analysing the results.
CO2 Apply CFD analysis to real engineering designs.
III SEMESTER
DESIGN FORMANUFACTURE AND
18MDE31 CO1 Describe the different types of manufacturing systems and comparetheirsuitability foreconomic production of various components and products.
ASSEMBLY
CO2Identify factors and causing mechanisms of the defects likely to occur withdifferent manufacturing processes in producing mechanical products and therelevant design approaches to rectify them.
CO3Select proper materials and manufacturing processes for designing
products/components by applying the relevant principles for ease and economic production.
EXPERIMENTALMECHANICS
18CAE321
CO1 Mount strain gages, take measurements and analyze the obtained data.
CO2 Design strain gage-based transducers for measuring specific loads.
CO3Describe the different methods photo elasticity for strain measurement viz, stressfreezing , and Moirés method.
CO4 Undertakeexperimentalinvestigationstoverifypredictionsbyothermethods.
CO5 Apply the principles and techniques of brittle coating analysis.
CO6 Apply the principles and techniques of holographic interferometer
Mechatronics SystemDesign
18MEA322 CO1 Describe mechatronic systems and overview of control systems & actuators.
CO2Identify and describe the different types of actuators used in mechatronicsystems
CO3Differentiate between various sensors, transducers and actuators and theirapplications.
CO4 Identify and describe the different types of speed- and positionfeedbackdevices.
CO5Relate various signal conditioning units, amplifiers, logic gates and their role inprogrammable logic controllers.
CO6cuss the importance of feedback in controlling physical systems with the use ofexamples.
CO7 lain the principle of operation of ac induction motor, dc motor, servomotor,and stepper motor
CO8 ntify and describe the types of controllers used in mechatronic systems
Robust Design 18MEA323
CO1Apply methods to analyze and identify opportunities to improve designprocesses for robustness.
CO2 Set up full and fraction Factorial experiment design.
CO3 Perform ANOVA and Hypothesis Testing.
CO4 Apply statistical models in analysing experimental data.
CO5 Lead product development activities that include robust design techniques.
Smart Materials andStructures
18CAE331
CO1 Understand the behavior and applicability of various smart materials.
CO2 Design simple models for smart structures & materials.
CO3 Devise experiments to verify the predictions.
CO4Judge the appropriate application of smart materials with respect to thefeasibility of their fabrication and implementation, and to the economic aspect
COMPOSITE MATERIALSTECHNOLOGY
18MDE332
CO1 Understand the use of fibre -reinforced composites in structural applications.
CO2Develop a basic understanding of the use of composite materials, micromechanicsof layered composites, analysis and design of composite structuresand failure analysis of laminated panels.
CO3Apply the basic micro-mechanics theories in the design of fibre reinforcedcomposites.
CO4 Analyze the performance of composites in engineering applications.
Acoustics and NoiseControl Engineering
18MDE333CO1
Distinguish among different sound generation and propagation mechanisms andtheir representations, understand different categories of noise effects onhumans.
CO2 Understand how to use pressure wave expressions to describe sound
transmission in different media.
CO3Analyze complex noise environments and predict sound levels in desiredlocations.
CO4 Evaluate acoustic enclosures, barriers and walls for effective noise control.
CO5 Become familiar with sound measurement instrumentation.
CO6Select appropriate noise control techniques for the solution of practical noiseproblems and evaluate their performance.
CO7Apply the noise control techniques considered in an integrated way to a practicaldesign case.
