To strengthen the region through imparting superior quality technical education and research; which enables the fulfillment of industrial challenge and establish itself as a Centre of Excellence in the field of Mechanical Engineering.
- To build an academic environment of teaching and lifelong learning for students to make them competitive in context with advance technological, economical and ecological changes.
- To enable the students to enhance their technical skills and communications through research, innovation and consultancy projects.
- To share and explore the accomplishments through didactic, enlightenment, R &D programs with technical institution in India and abroad.
|
PEO1. |
Graduates will be able to pursue successful professional career in Mechanical Engineering with sound technical and managerial capabilities to meet the needs of the society. |
|
PEO2. |
Graduates will have skills and knowledge to formulate, analyze and solve problems in mechanical engineering to meet challenges globally. |
|
PEO3. |
Graduates will have the readiness for continuous learning by pursuing higher education and research in the allied areas of science and technology.
|
PO1 | Engineering knowledge: An ability to apply the knowledge of mathematics, science, engineering fundamentals, and an engineering specialization to get the solution of the engineering problems. |
PO2 | Problem analysis: Ability to Identify, formulates, review research literature, and analyze complex engineering problems. |
PO3 | Design/development of solutions: Ability to design solutions for complex engineering problems by considering social, economical and environmental aspects. |
PO4 | Conduct investigations of complex problems: Use research-based knowledge to design, conduct analyse experiments to get valid conclusion. |
PO5 | Modern tool usage: ability to create, select, and apply appropriate techniques, and to model complex engineering activities with an understanding of the limitations. |
PO6 | The engineer and society: Ability to apply knowledge by considering social health, safety, legal and cultural issues. |
PO7 | Environment and sustainability: Understanding of the impact of the adopted engineering solutions in social and environmental contexts. |
PO8 | Ethics: Understanding of the ethical issues of the Mechanical engineering and applying ethical principles in engineering practices. |
PO9 | Individual and teamwork: Ability to work effectively as an individual or in team, as a member or as a leader. |
PO10 | Communication: An ability to communicate clearly and effectively through different modes of communication. |
PO11 | Project management and finance: Ability to handle project and to manage finance related issue |
PO12 | Life-long learning: Recognize the need for, and have the preparation and ability to engage in independent and life-long learning. |
| PSO1 | Apply their understanding in the realm of Design, Production and thermal fluid sciences to solve engineering problems using latest technologies. |
| PSO2 | Students will be well equipped with industrial management skills and interdisciplinary technologies |
| PSO3 | Extend and implement innovative thinking on product design and development with the aid of modern tools. |
Correlation- 1: Low, 2: Medium, 3: High
|
PEO Statements |
M1 |
M2 |
M3 |
|
PEO1: – Graduates will be able to pursue a successful professional career in Mechanical Engineering with sound technical and managerial capabilities to meet the needs of society. |
3 |
2 |
3 |
|
PEO2: – Graduates will have the skills and knowledge to formulate, analyze, and solve problems in mechanical engineering to meet challenges globally. |
2 |
3 |
3 |
|
PEO3: – Graduates will have the readiness for continuous learning by pursuing higher education and research in the allied areas of science and technology. |
2 |
2 |
2 |
Justification of PEOs and Mission Statement of the Mechanical Department
|
Mission of the Department |
PEOs of the Department |
||
|
PEO1 |
PEO2 |
PEO3 |
|
|
M1 To build an academic environment of teaching and lifelong learning for students to make them competitive in the context of advanced technological, economic, and ecological changes. |
Sound technical and managerial capabilities to meet the needs of society. |
Skills and knowledge to formulate, analyze and solve problems in mechanical engineering to meet challenges globally. |
Continuous learning by pursuing higher education and research in the allied areas of science and technology |
|
M2 To enable the students to enhance their technical skills and communications through research, innovation, and consultancy projects |
Sound technical and managerial capabilities to meet the needs of society. |
To formulate, analyze and solve problems in mechanical engineering to meet challenges globally |
By pursuing higher education and research in the allied areas of science and technology |
|
M3 To share and explore the accomplishments through didactic, enlightenment, R&D programs with technical institutions in India and abroad. |
To pursue successful professional career in Mechanical Engineering with sound technical and managerial capabilities to meet the needs of society. |
Skills and knowledge to formulate, analyze and solve problems in mechanical engineering to meet challenges globally |
By pursuing higher education and research in the allied areas of science and technology
|
|
Semester No: 1st |
|
||
|
Course Title: |
Engineering Graphics & Design |
Course Code: |
100102 |
|
Course Outcome No. |
Course Outcome Statement |
||
|
CO1 |
Explain the principles of engineering graphics, drawing instruments, lettering, scales, and the construction of conic sections and cycloidal curves. |
||
|
CO2 |
Apply the principles of orthographic projection to draw projections of points, lines, and planes using standard conventions. |
||
|
CO3 |
Analyse the projections and auxiliary views of regular solids inclined to one or both reference planes. |
||
|
CO4 |
Construct sectional views and develop the surfaces of right regular solids and simple engineering objects. |
||
|
CO5 |
Apply isometric projection principles and CAD tools to generate isometric and orthographic views of simple and compound solids. |
||
|
Semester No: 1st |
|
||
|
Course Title: |
Engineering Graphics & Design |
Course Code: |
100102P |
|
Course Outcome No. |
Course Outcome Statement |
||
|
CO1 |
Explain the principles of engineering graphics, drawing instruments, lettering, scales, and construction of conic sections and cycloidal curves. |
||
|
CO2 |
Apply the principles of orthographic projection to draw projections of points, lines, and planes using standard conventions. |
||
|
CO3 |
Analyze the projections and auxiliary views of regular solids inclined to one or both reference planes. |
||
|
CO4 |
Construct sectional views and develop the surfaces of right regular solids and simple engineering objects. |
||
|
CO5 |
Apply isometric projection principles and CAD tools to generate isometric and orthographic views of simple and compound solids. |
||
|
Semester No: 1st |
|
||
|
Course Title: |
Basic Electrical Engineering |
Course Code: |
100101 |
|
Course Outcome No. |
Course Outcome Statement |
||
|
CO1 |
Recall fundamental concepts of Electrical Engineering. |
||
|
CO2 |
Illustrate the basic principles and behaviour of AC circuits. |
||
|
CO3 |
Explain the operating principle of transformers with reference to magnetic circuits. |
||
|
CO4 |
Classify and compare different types of electrical machines. |
||
|
CO5 |
Classify various electrical measuring instruments and explain their operating principles. |
||
|
Semester No: 1st |
|
||
|
Course Title: |
Physics (Electromagnetism) |
Course Code: |
102101 |
|
Course Outcome No. |
Course Outcome Statement |
||
|
CO1 |
To Evaluate electric field and electrostatic potential for charge distribution in air/ vacuum and dielectric medium with the help of Laplace equation, Poisson equation, and by Apply the method of image. |
||
|
CO2 |
To Remember and Apply Bio-Savart law, divergence and curl of static magnetic field; vector potential and evaluate it for a given magnetic field using stokes’ theorem; the equation for the vector potential and its solution for given current densities. To Analyze magnetization and associated bound currents; auxiliary magnetic field; To Apply boundary conditions on and To Evaluate magnetic field due to simple magnets like a bar magnet; magnetic susceptibility and ferromagnetic, paramagnetic and diamagnetic materials; Conceptual discussion of magnetic field in presence of magnetic materials. |
||
|
CO3 |
To Analyze Faraday’s law in terms of emf produced by changing magnetic flux; To Evaluate equivalence of faraday’s law and motional emf; Lenz’s law; electromagnetic breaking and its applications; differential form of faraday’s law expressing curl of electric field in terms of time-derivative of magnetic field and calculating electric field due to changing magnetic fields in quasi-static approximation; energy stored in a magnetic field |
||
|
CO4 |
To evaluate the continuity equation for current densities; Apply equation for the curl of magnetic field to satisfy continuity equation; displace current and magnetic field arising from the time-dependent electric field; To Analyze magnetic field due to changing electric fields in quasi-static approximation. To Remember Maxwell’s equation in vacuum and non-conducting medium; create energy in an electromagnetic field; To Analyze flow of energy and Poynting vector with examples. Qualitative discussion of momentum in electromagnetic fields. |
||
|
CO5 |
To Evaluate the wave equation of an electromagnetic waves in vacuum, To Analyze their transverse nature and polarization; Conceptual relation between electric and magnetic fields of an electromagnetic wave To Analyze energy, momentum carried by electromagnetic waves and resultant pressure. To Evaluate Reflection and transmission of electromagnetic waves from a non-conducting medium-vacuum interface for normal incidence |
||
|
Semester No: 1st |
|
||
|
Course Title: |
Mathematics – I (Calculus and Linear Algebra) |
Course Code: |
102102 |
|
Course Outcome No. |
Course Outcome Statement |
||
|
CO1 |
To comprehend the differentiability and continuity of the function. To analyze the convergence of an infinite series. To evaluate the curvature of the given curve. |
||
|
CO2 |
To comprehend beta and gamma functions. To apply the concept of definite integrals for the evaluation of arc length, surface and volume of the revolution of a given curve. |
||
|
CO3 |
To comprehend Rolle’s theorem and Mean value theorems. To apply the idea of these theorems in variety of problems. To evaluate limits of a function having indeterminate forms. |
||
|
CO4 |
To analyze Fourier series expansions of different functions in a given range. |
||
|
CO5 |
To apply rank of a matrix in determining the consistency of a system of linear equations |
||
|
Semester No: 2nd |
|
||
|
Course Title: |
Chemistry |
Course Code: |
100203 |
|
Course Outcome No. |
Course Outcome Statement |
||
|
CO1 |
Apply the fundamental concepts of chemical bonding, molecular structure, and the properties of materials relevant to engineering applications. |
||
|
CO2 |
Comprehend and apply the principles of various spectroscopic techniques, such as UV-Visible, IR, and NMR spectroscopy, to analyse the structure and properties of chemical compounds used in engineering materials and processes. |
||
|
CO3 |
Demonstrate knowledge of intermolecular forces and properties of gases |
||
|
CO4 |
Apply and analyse the principles of properties of thermodynamics and water chemistry, classifying elements and their properties. |
||
|
CO5 |
Critical analysis of the fundamentals of organic reaction mechanisms and functional group transformations. |
||
|
Semester No: 2nd |
|
||
|
Course Title: |
Chemistry |
Course Code: |
100203P |
|
Course Outcome No. |
Course Outcome Statement |
||
|
CO1 |
Analytical & Water Chemistry Perform quantitative and qualitative analysis to assess water quality and chemical composition using titration, ion exchange, and chromatography. |
||
|
CO2 |
Physical & Surface Phenomena Determine the physical properties of liquids and solutes, including transport properties, colligative behaviour, and surface adsorption. |
||
|
CO3 |
Instrumental & Kinetic Studies Apply instrumental methods like conductometry and potentiometry to study electrochemical cells and determine the rates of chemical reactions. |
||
|
CO4 |
Molecular Synthesis & Structural Design Demonstrate skills in chemical synthesis and use models to understand 3D molecular lattices and potential energy landscapes. |
||
|
Semester No: 2nd |
|
||
|
Course Title: |
Programming For Problem Solving
|
Course Code: |
100204 |
|
Course Outcome No. |
Course Outcome Statement |
||
|
CO1 |
TO FORMULATE THE ALGORITHMS FOR SIMPLE PROBLEMS |
||
|
CO2 |
TO TRANSLATE GIVEN ALGORITHMS TO A WORKING AND CORRECT PROGRAM |
||
|
CO3 |
TO BE ABLE TO IDENTIFY AND CORRECT SYNTAX, LOGICAL ERRORS ENCOUNTERED AT RUN TIME |
||
|
CO4 |
TO BE ABLE TO WRITE ITERATIVE AS WELL AS RECURSIVE PROGRAMS |
||
|
CO5 |
TO BE ABLE TO REPRESENT DATA IN ARRAYS, STRINGS AND STRUCTURES AND MANIPULATE THEM THROUGH A PROGRAM |
||
|
CO6 |
TO BE ABLE TO DECLARE POINTERS OF DIFFERENT TYPES AND USE THEM IN DEFINING SELF-REFERENTIAL STRUCTURES. |
||
|
Semester No: 2nd |
|
||
|
Course Title: |
Programming For Problem Solving
|
Course Code: |
100204P |
|
Course Outcome No. |
Course Outcome Statement |
||
|
CO1 |
TO FORMULATE THE ALGORITHMS FOR SIMPLE PROBLEMS |
||
|
CO2 |
TO TRANSLATE GIVEN ALGORITHMS TO A WORKING AND CORRECT PROGRAM |
||
|
CO3 |
TO BE ABLE TO IDENTIFY AND CORRECT SYNTAX, LOGICAL ERRORS ENCOUNTERED AT RUN TIME |
||
|
CO4 |
TO BE ABLE TO WRITE ITERATIVE AS WELL AS RECURSIVE PROGRAMS |
||
|
CO5 |
TO BE ABLE TO REPRESENT DATA IN ARRAYS, STRINGS AND STRUCTURES AND MANIPULATE THEM THROUGH A PROGRAM |
||
|
CO6 |
TO BE ABLE TO DECLARE POINTERS OF DIFFERENT TYPES AND USE THEM IN DEFINING SELF-REFERENTIAL STRUCTURES. |
||
|
Semester No: 2nd |
|
||
|
Course Title: |
Workshop Manufacturing Practices |
Course Code: |
100205 |
|
Course Outcome No. |
Course Outcome Statement |
||
|
CO1 |
Explain various manufacturing methods such as casting, forming, machining, joining, and advanced manufacturing processes. |
||
|
CO2 |
Demonstrate basic understanding and applications of CNC machining and additive manufacturing processes. |
||
|
CO3 |
Perform fitting operations, use power tools safely, and carry out basic carpentry practices. |
||
|
CO4 |
Execute basic plastic moulding, glass cutting, metal casting, welding, brazing, and soldering operations following safety norms. |
||
|
CO5 |
Apply workshop practices, safety procedures, teamwork, and professional ethics in manufacturing activities. |
||
|
Semester No: 2nd |
|
||
|
Course Title: |
Workshop Manufacturing Practices |
Course Code: |
100205P |
|
Course Outcome No. |
Course Outcome Statement |
||
|
CO1 |
Demonstrate safe operation and basic machining skills in the machine shop and fitting shop using standard tools and equipment. |
||
|
CO2 |
Perform carpentry operations such as measuring, marking, cutting, and joining to fabricate simple wooden components as per drawings. |
||
|
CO3 |
Execute arc welding and gas welding processes to produce sound joints while adhering to safety and quality practices. |
||
|
CO4 |
Carry out casting and smithy operations to shape metal components and understand material behaviour during heating and solidification. |
||
|
CO5 |
Fabricate simple components using plastic moulding, glass cutting, and 3-D printing techniques, demonstrating awareness of modern manufacturing practices. |
||
|
Semester No: 2nd |
|
||
|
Course Title: |
English |
Course Code: |
100206 |
|
Course Outcome No. |
Course Outcome Statement |
||
|
CO1 |
To analyze the fundamental of critical thinking to reading writing and editing |
||
|
CO2 |
To identify problem areas in writing |
||
|
CO3 |
To develop the speaking ability in English with clarity and precision |
||
|
CO4 |
To produce & develop presentation skills and abilities in team work |
||
|
CO5 |
To analyze the fundamental of critical thinking to reading writing and editing |
||
|
Semester No: 2nd |
|
||
|
Course Title: |
Mathematics – II (Ode & Complex Variables) |
Course Code: |
102202 |
|
Course Outcome No. |
Course Outcome Statement |
||
|
CO1 |
Able to evaluate multiple integrals and apply the concept to find areas, volumes and problems of Integrals and Vector calculus. |
||
|
CO2 |
Able to comprehend the basic concept of an ordinary differential equation. |
||
|
CO3 |
Able to Create Mathematical modeling of real-life problems in different engineering applications by using the concept of Ordinary Differential Equation. |
||
|
CO4 |
To comprehend the fundamental concepts of function, Limit, and Analytic function of a complex variable and complex number system. |
||
|
CO5 |
Able to analyse complex engineering problems of contour/Complex integration by using the Cauchy-integral formula and the Cauchy Residue Theorems. |
||
|
Semester No: 3rd |
|
||
|
Course Title: |
Biology For Engineers |
Course Code: |
100301 |
|
Course Outcome No. |
Course Outcome Statement |
||
|
CO1 |
Explain fundamental biological concepts such as cell structure, biomolecules, enzymes, and genetics relevant to engineering applications. |
||
|
CO2 |
Illustrate biological processes and mechanisms and relate them to engineering systems and bio-inspired designs. |
||
|
CO3 |
Apply principles of biology to solve basic engineering problems related to biomaterials, biomechanics, and bio-systems. |
||
|
CO4 |
Analyze biological data and structure–function relationships to interpret behavior of living systems and engineered bio-systems. |
||
|
CO5 |
Evaluate applications of biological principles in emerging engineering technologies such as biomedical devices, biosensors, and bio-engineering solutions. |
||
|
Semester No: 3rd |
|
||
|
Course Title: |
Basic Electronics Engineering |
Course Code: |
100303 |
|
Course Outcome No. |
Course Outcome Statement |
||
|
CO1 |
Understand the principles of semiconductor devices and their applications. |
||
|
CO2 |
Design an application using an Operational amplifier |
||
|
CO3 |
Understand the working of timing circuits and oscillators. |
||
|
CO4 |
Apply flip flops and logic gates to build various digital systems. |
||
|
CO5 |
Learn the basics of Electronic communication systems. |
||
|
Semester No: 3rd |
|
||
|
Course Title: |
Engineering Mechanics |
Course Code: |
100309 |
|
Course Outcome No. |
Course Outcome Statement |
||
|
CO1 |
Apply the principles of statics to analyze coplanar and non-coplanar force systems and equilibrium of particles and rigid bodies. |
||
|
CO2 |
Analyze structures such as trusses, frames, and machines using equilibrium equations to determine internal forces and reactions. |
||
|
CO3 |
Evaluate frictional forces and apply the concepts of dry friction to solve engineering problems involving wedges, ladders, and belt drives. |
||
|
CO4 |
Apply the fundamentals of kinematics and kinetics to analyze motion, work–energy, and impulse–momentum problems. |
||
|
Semester No: 3rd |
|
||
|
Course Title: |
Engineering Mechanics |
Course Code: |
100309P |
|
Course Outcome No. |
Course Outcome Statement |
||
|
CO1 |
Perform experiments related to force systems and equilibrium and interpret results using fundamental principles of engineering mechanics. |
||
|
CO2 |
Conduct experiments on friction, centroid, and moment of inertia, and analyze experimental data to validate theoretical concepts. |
||
|
CO3 |
Apply experimental and analytical techniques to solve mechanics problems and present results effectively using appropriate tools. |
||
|
Semester No: 3rd |
|
||
|
Course Title: |
Mathematics-III (Pde, Probability and Statistics) |
Course Code: |
100312 |
|
Course Outcome No. |
Course Outcome Statement |
||
|
CO1 |
Able to comprehend the application of partial differential equations in engineering like heat equation, wave equation and Laplace equation. |
||
|
CO2 |
Abel to create mathematical modelling of natural problems in the different Engineering applications by using special functions like Legendre’s and Bessel’s functions. |
||
|
CO3 |
Abel to apply probability theory to analyze discrete and continuous random variables and Probablity distribution. |
||
|
CO4 |
Able to apply the concept of correlation, moments, skewness, and kurtosis in stastistical data analysis. |
||
|
CO5 |
Able to describe and analyse curve fitting and sampling theory in engineering applications. |
||
|
Semester No: 3rd |
|
||
|
Course Title: |
Thermodynamics |
Course Code: |
102304 |
|
Course Outcome No. |
Course Outcome Statement |
||
|
CO1 |
Explain basic thermodynamic concepts such as system, properties, processes, work, and energy. |
||
|
CO2 |
Apply the First Law of Thermodynamics to analyse closed systems and control volumes. |
||
|
CO3 |
Determine thermodynamic properties of pure substances, gases, and gas mixtures. |
||
|
CO4 |
Analyse the performance of basic engineering devices using energy and entropy principles. |
||
|
CO5 |
Analyse thermodynamic cycles, irreversibility, and psychrometric processes to evaluate the system. |
||
|
Semester No: 3rd |
|
||
|
Course Title: |
Internship |
Course Code: |
100399P |
|
Course Outcome No. |
Course Outcome Statement |
||
|
CO1 |
To apply theoretical knowledge and technical skills acquired in the classroom to solve real-world problems and execute assigned tasks. |
||
|
CO2 |
To develop and refine oral and written communication skills through communicate complex ideas effectively through trainer/faculty member, internship report and attending interview and viva voce. |
||
|
CO3 |
To get exposure to team-work, leadership quality and the ability to work productively within a multidisciplinary team. |
||
|
CO4 |
To identify and adhere to the ethical standards, legal regulations, and professional codes of conduct specific to the industry/Institute. |
||
|
Semester No: 3rd |
|
||
|
Course Title: |
Machine drawing |
Course Code: |
102302P |
|
Course Outcome No. |
Course Outcome Statement |
||
|
CO1 |
Interpret engineering drawings and apply BIS standards, symbols, and dimensioning practices for machine components. |
||
|
CO2 |
Construct orthographic projections and sectional views of machine parts from given pictorial views using conventional drawing methods. |
||
|
CO3 |
Prepare detailed and assembly drawings of machine elements such as fasteners, couplings, bearings, and valves following standard drawing practices. |
||
|
CO4 |
Develop working drawings of mechanical components and assemblies with appropriate tolerances, fits, and surface finish specifications. |
||
|
CO5 |
Create two-dimensional and three-dimensional models of machine components and assemblies using SolidWorks to visualize design intent and improve drafting accuracy. |
||
|
Semester No: 4th |
|
||
|
Course Title: |
Applied Thermodynamics |
Course Code: |
102401 |
|
Course Outcome No. |
Course Outcome Statement |
||
|
CO1 |
Explain the properties of fuels and the basics of combustion and exhaust gas analysis. |
||
|
CO2 |
Apply thermodynamic and chemical equilibrium principles to analyze combustion processes. |
||
|
CO3 |
Apply thermodynamic principles to evaluate gas power cycles, vapor power cycles, and refrigeration cycles. |
||
|
CO4 |
Analyze compressible flow in nozzles and diffusers, including choking and shock phenomena. |
||
|
CO5 |
Analyze the performance of steam turbines and reciprocating compressors. |
||
|
Semester No: 4th |
|
||
|
Course Title: |
Engineering Materials |
Course Code: |
102402 |
|
Course Outcome No. |
Course Outcome Statement |
||
|
CO1 |
To Analyze engineering materials on the basis of structure and properties for engineering applications. |
||
|
CO2 |
To Analyze the binary phase diagrams of alloys. |
||
|
CO3 |
Perform and evaluate mechanical property tests (tensile, hardness, NDT) and differentiate between engineering and true stress-strain behavior in materials. |
||
|
CO4 |
To Apply the heat treatment processes that will produce a specified microstructure using isothermal transformation diagram for iron-carbon alloy. |
||
|
CO5 |
To Select specific ferrous and non-ferrous alloys (Stainless steel, Aluminum, Titanium, and Superalloys) for engineering applications based on their composition and properties. |
||
|
Semester No: 4th |
|
||
|
Course Title: |
Fluid Mechanics |
Course Code: |
102403 |
|
Course Outcome No. |
Course Outcome Statement |
||
|
CO1 |
Explain the fundamental properties of fluids and the concepts of fluid statics, including pressure measurement and hydrostatic forces on submerged surfaces. |
||
|
CO2 |
Apply the principles of fluid kinematics and dynamics to analyze fluid motion using continuity and energy equations. |
||
|
CO3 |
Analyze internal and external flows through pipes and around submerged bodies, considering losses, flow regimes, and dimensional analysis. |
||
|
CO4 |
Evaluate the performance of hydraulic machines and flow measurement devices using governing equations and experimental data. |
||
|
Semester No: 4th |
|
||
|
Course Title: |
Fluid Mechanics |
Course Code: |
102403P |
|
Course Outcome No. |
Course Outcome Statement |
||
|
CO1 |
Conduct experiments to determine fluid properties and flow parameters, and interpret the results using fundamental principles of fluid mechanics. |
||
|
CO2 |
Analyze experimental data related to flow measurement devices and pipe flow to validate theoretical concepts and performance characteristics. |
||
|
CO3 |
Evaluate the performance of hydraulic machines through laboratory experiments and present the results effectively using appropriate tools and techniques. |
||
|
Semester No: 4th |
|
||
|
Course Title: |
Instrumentation & Control |
Course Code: |
102404 |
|
Course Outcome No. |
Course Outcome Statement |
||
|
CO1 |
|
||
|
CO2 |
|
||
|
CO3 |
|
||
|
CO4 |
|
||
|
CO5 |
|
||
|
Semester No: 4th |
|
||
|
Course Title: |
Strength Of Materials |
Course Code: |
102405 |
|
Course Outcome No. |
Course Outcome Statement |
||
|
CO1 |
To analyse the internal behaviour of solids by calculating stresses, strains, and elastic constants, and determine principal stresses using Mohr’s Circle and failure theories. |
||
|
CO2 |
To construct Shear Force (SFD) and Bending Moment Diagrams (BMD) for various types of beams and evaluate the distribution of bending stress and shear stresses across sections. |
||
|
CO3 |
To compute the slope and deflection of various types of beams under different loads using mathematical tools like double integration and Maxwell’s reciprocal theorem |
||
|
CO4 |
To examine the effects of torque on circular and stepped shafts and analyze the stresses and deflections in helical springs under axial loading. |
||
|
CO5 |
To evaluate the structural integrity of thin and thick pressure vessels by calculating axial, hoop, and radial stresses in cylinders and spherical shells. |
||
|
Semester No: 4th |
|
||
|
Course Title: |
Strength Of Materials |
Course Code: |
102405P |
|
Course Outcome No. |
Course Outcome Statement |
||
|
CO1 |
To understand the experimental procedure and Lab report preparation |
||
|
CO2 |
To determine elastic constants like Modulus of Elasticity (E) and the Modulus of Rigidity (G) of a material |
||
|
CO3 |
To compare the surface resistance of different materials using Rockwell, Brinell, and Vickers scales to select appropriate materials for wear resistance. |
||
|
CO4 |
To evaluate different mechanical properties like compressive strength, shear strength, flexural strength, toughness and energy absorption capacity of materials. |
||
|
CO5 |
To verify the deflection profile of continuous beams under various loading and support conditions using analytical formulas. |
||
|
Semester No: 5th |
|
||
|
Course Title: |
Fluid Machinery |
Course Code: |
102501 |
|
Course Outcome No. |
Course Outcome Statement |
||
|
CO1 |
Apply Euler’s equation for turbomachinery to analyze energy transfer in fluid machines. |
||
|
CO2 |
Perform preliminary design of pumps and turbines using principles of dimensional analysis and similitude. |
||
|
CO3 |
Analyze the performance characteristics and working mechanisms of Pelton, Francis, and Kaplan turbines. |
||
|
CO4 |
Evaluate the operational parameters and performance curves of positive displacement and rotodynamic pumps. |
||
|
CO5 |
Design a comprehensive layout for a hydroelectric power plant considering hydrological data and power demand. |
||
|
Semester No: 5th |
|
||
|
Course Title: |
Fluid Machinery |
Course Code: |
102501P |
|
Course Outcome No. |
Course Outcome Statement |
||
|
CO1 |
Validate Euler’s energy transfer theory by conducting “Impact of Jet” experiments on various vane shapes. |
||
|
CO2 |
Analyze the scaling laws and similitude by comparing performance data of model turbines at varying speeds. |
||
|
CO3 |
Evaluate the main and operating characteristic curves of Pelton and Francis turbines to find the Best Efficiency Point (BEP). |
||
|
CO4 |
Examine the performance of Rotodynamic and Positive Displacement pumps, including the study of cavitation and slip. |
||
|
CO5 |
Synthesize experimental data to propose a turbine selection for a simulated site condition (Hydro-plant planning). |
||
|
Semester No: 5th |
|
||
|
Course Title: |
Heat Transfer |
Course Code: |
102502 |
|
Course Outcome No. |
Course Outcome Statement |
||
|
CO1 |
To explain the fundamental principles of heat and mass transfer, including conduction, convection, radiation, and the associated governing equations. |
||
|
CO2 |
To apply analytical and approximate methods to solve steady and unsteady conduction heat transfer problems in Cartesian, cylindrical, and spherical geometries. |
||
|
CO3 |
To analyse forced and natural convection heat transfer problems for internal and external flows using dimensionless parameters and empirical correlations. |
||
|
CO4 |
To evaluate radiation heat exchange and heat exchanger performance using radiative properties, view factors, LMTD, and ε–NTU methods. |
||
|
CO5 |
To apply boiling, condensation, and heat–mass transfer analogy concepts to analyse thermal and mass transfer systems. |
||
|
Semester No: 5th |
|
||
|
Course Title: |
Heat Transfer |
Course Code: |
102502P |
|
Course Outcome No. |
Course Outcome Statement |
||
|
CO1 |
To Apply the principles of heat conduction to experimentally determine thermal conductivity of materials and the overall heat transfer coefficient of composite walls. |
||
|
CO2 |
To Analyze the performance of extended surfaces (pin fins) under natural and forced convection by studying temperature distribution and fin effectiveness. |
||
|
CO3 |
To Evaluate convective heat transfer coefficients for free and forced convection in internal and external flow systems using experimental observations. |
||
|
CO4 |
To Determine radiative heat transfer parameters such as surface emissivity and the Stefan–Boltzmann constant through laboratory experiments. |
||
|
CO5 |
To Assess the performance of parallel-flow and counter-flow heat exchangers using LMTD and effectiveness methods. |
||
|
Semester No: 5th |
|
||
|
Course Title: |
Kinematics of Machine |
Course Code: |
102503 |
|
Course Outcome No. |
Course Outcome Statement |
||
|
CO1 |
To explain fundamental kinematic concepts, classification of mechanisms, degrees of freedom, mobility, Grashof’s law, and kinematic inversions. |
||
|
CO2 |
To apply kinematic principles to determine displacement, velocity, and acceleration of plane mechanisms using graphical and analytical methods. |
||
|
CO3 |
To apply friction and dynamics principles to analyze belt drives, clutches, and braking systems. |
||
|
CO4 |
To analyze spur gears and gear trains to determine velocity ratios, contact ratio, interference, and undercutting. |
||
|
CO5 |
To analyze balancing of rotating masses and the performance characteristics of governors with respect to stability, sensitivity, and isochronism. |
||
|
Semester No: 5th |
|
||
|
Course Title: |
Manufacturing Processes |
Course Code: |
102504 |
|
Course Outcome No. |
Course Outcome Statement |
||
|
CO1 |
Explain the principles, equipment, and defects associated with conventional manufacturing processes such as metal casting and moulding, including heat transfer, solidification, shrinkage, riser design, and residual stresses. |
||
|
CO2 |
Apply concepts of plastic deformation, yield criteria, and hot and cold working to analyse bulk and sheet metal forming processes and estimate forming loads. |
||
|
CO3 |
Analyse metal cutting mechanisms and machining processes by evaluating cutting forces, chip formation, tool wear, surface finish, machinability, and CNC machining principles. |
||
|
CO4 |
Describe and compare joining and additive manufacturing processes, including welding, brazing, soldering, adhesive bonding, rapid prototyping, and rapid tooling. |
||
|
CO5 |
Explain the working principles and applications of machine tools and finishing processes such as turning, milling, drilling, grinding, and super-finishing operations. |
||
|
Semester No: 5th |
|
||
|
Course Title: |
Manufacturing Processes |
Course Code: |
102504P |
|
Course Outcome No. |
Course Outcome Statement |
||
|
CO1 |
Perform metal casting operations including pattern making, mould preparation, melting, and casting, and evaluate sand properties and casting defects. |
||
|
CO2 |
Execute welding processes such as arc welding, gas welding, and spot welding, and analyze weld quality, joint types, and process parameters. |
||
|
CO3 |
Carry out sheet metal and press working operations such as blanking, piercing, bending, and forming, and interpret the working of simple, compound, and progressive press tools. |
||
|
CO4 |
Perform machining operations on conventional machine tools such as lathe, milling, drilling, grinding, and shaping machines, and evaluate machining parameters and surface quality. |
||
|
CO5 |
Analyze manufacturing process parameters, compare different manufacturing techniques, and demonstrate safe laboratory practices, teamwork, and problem-solving skills in manufacturing applications. |
||
|
Semester No: 5th |
|
||
|
Course Title: |
Summer Entrepreneurship – II |
Course Code: |
100510P |
|
Course Outcome No. |
Course Outcome Statement |
||
|
CO1 |
To provide industrial exposure to student to apply theoretical knowledge and technical skills acquired in the classroom to solve real-world problems and execute tasks within a professional environment. |
||
|
CO2 |
To develop and refine oral and written communication skills through communicate complex ideas effectively through professional channels, oral presentations, technical documentation, internship report and attending interview and viva voce. |
||
|
CO3 |
To get exposure to team-work, leadership quality and the ability to work productively within a multidisciplinary team. |
||
|
CO4 |
To identify and adhere to the ethical standards, legal regulations, and professional codes of conduct specific to the industry. |
||
|
Semester No: 6th |
|
||
|
Course Title: |
Design Of Machine Elements |
Course Code: |
102601 |
|
Course Outcome No. |
Course Outcome Statement |
||
|
CO1 |
Learn and implement the fundamental steps, factors, and economical and practical considerations in the mechanical design process, including material selection and failure criteria. |
||
|
CO2 |
Investigate and design shafts under various loading conditions, considering strength, deflection, and critical speed effects. |
||
|
CO3 |
Determine stresses and design riveted, bolted, and welded joints for central and eccentric loads in mechanical assemblies. |
||
|
CO4 |
Design friction elements such as clutches and brakes using appropriate assumptions and performance criteria. |
||
|
CO5 |
Analyze and design key transmission and spring elements, including gears and various types of springs for strength and fatigue resistance. |
||
|
Semester No: 6th |
|
||
|
Course Title: |
Design Of Machine Elements |
Course Code: |
102601P |
|
Course Outcome No. |
Course Outcome Statement |
||
|
CO1 |
Understand and apply design procedures for mechanical joints and machine elements. |
||
|
CO2 |
Analyze stresses and strength of shafts, keys, and joints under different loading conditions.
|
||
|
CO3 |
Design and prepare detailed drawings of machine elements as per standards. |
||
|
CO4 |
Conduct experiments on bearings and interpret performance characteristics. |
||
|
CO5 |
Use standard design data, codes, and modern tools for mechanical component design. |
||
|
Semester No: 6th |
|
||
|
Course Title: |
Dynamics Of Machinery |
Course Code: |
102602 |
|
Course Outcome No. |
Course Outcome Statement |
||
|
CO1 |
To apply principles of dynamics to perform force analysis of mechanisms and evaluate correction torque and dynamic forces in machines. |
||
|
CO2 |
To apply turning moment concepts to analyze fluctuation of energy and speed in engines and determine flywheel parameters. |
||
|
CO3 |
To kinematic and dynamic principles to design and analyze cam–follower systems using graphical methods. |
||
|
CO4 |
To analyze gyroscopic effects and inertia forces in rotating and reciprocating systems to assess their influence on machine stability. |
||
|
CO5 |
To analyze mechanical vibration problems involving single and multi-degree-of-freedom systems, damping, balancing, and vibration control techniques. |
||
|
Semester No: 6th |
|
||
|
Course Title: |
Dynamics Of Machinery |
Course Code: |
102602P |
|
Course Outcome No. |
Course Outcome Statement |
||
|
CO1 |
Identify and explain different types of links, kinematic pairs, chains, mechanisms, and their inversions. |
||
|
CO2 |
Analyze velocity characteristics of four-bar and slider–crank mechanisms using graphical methods. |
||
|
CO3 |
Evaluate the performance of belt drives and cam–follower mechanisms by determining frictional characteristics and plotting displacement diagrams. |
||
|
CO4 |
Identify and analyze different types of gears and gear trains used in mechanical systems. |
||
|
CO5 |
Conduct experiments on governors, gyroscopic systems, balancing of rotating parts, and inertia measurement to analyze stability, sensitivity, and dynamic behavior. |
||
|
CO6 |
Evaluate dynamometer performance and determine the critical (whirling) speed of shafts using standard experimental methods. |
||
|
Semester No: 6th |
|
||
|
Course Title: |
Manufacturing Technology |
Course Code: |
102603 |
|
Course Outcome No. |
Course Outcome Statement |
||
|
CO1 |
Design specialized tooling including jigs, fixtures, press tools, and forging dies for conventional manufacturing. |
||
|
CO2 |
Apply principles of limits, fits, tolerances, and gauge design to ensure precision in manufacturing and assembly. |
||
|
CO3 |
Analyze surface integrity, tool wear, and alignment using advanced metrological techniques and interferometry. |
||
|
CO4 |
Develop efficient process plans for assembly practices and selective assembly using appropriate material handling devices. |
||
|
CO5 |
Evaluate the process parameters, material removal rates (MRR), and surface finish of thermal and chemical unconventional machining processes. |
||
|
Semester No: 6th |
|
||
|
Course Title: |
Manufacturing Technology |
Course Code: |
102603P |
|
Course Outcome No. |
Course Outcome Statement |
||
|
CO1 |
Measure linear and angular dimensions of workpieces using precision instruments like Sine bars, Bevel protractors, and Slip gauges. |
||
|
CO2 |
Analyze geometric alignments and surface flatnesses using high-sensitivity optical tools like Autocollimators and Optical flats. |
||
|
CO3 |
Evaluate cutting tool forces in machining operations using Lathe and Drill tool dynamometers to understand tool-work interaction. |
||
|
CO4 |
Determine screw thread and gear tooth parameters using multi-wire methods and specialized micrometers. |
||
|
CO5 |
Assess surface integrity and part quality using mechanical comparators and Tally Surf profilometers. |
||
|
Semester No: 6th |
|
||
|
Course Title: |
Automation In Manufacturing |
Course Code: |
102605 |
|
Course Outcome No. |
Course Outcome Statement |
||
|
CO1 |
Explain the need, principles, and current trends of automation in machine tool–based manufacturing systems, including rigid and flexible automation. |
||
|
CO2 |
Apply CAD and CAM concepts for geometric modelling, downstream applications, and integration with manufacturing systems. |
||
|
CO3 |
Demonstrate the working and application of CNC systems, PLCs, sensors, pneumatics, and hydraulics in automated manufacturing environments. |
||
|
CO4 |
Analyze and design low-cost automation solutions using mechanical, electro-mechanical, pneumatic, and hydraulic systems for industrial case studies. |
||
|
CO5 |
Develop and evaluate models and simulations for product design and manufacturing processes, incorporating optimisation techniques for industrial applications. |
||
|
Semester No: 6th |
|
||
|
Course Title: |
Automation In Manufacturing |
Course Code: |
102605P |
|
Course Outcome No. |
Course Outcome Statement |
||
|
CO1 |
Critically analyze industrial automation systems through structured case studies covering automated manufacturing, computer-aided process planning, quality control, and flexible manufacturing systems. |
||
|
CO2 |
Design, develop, and execute CNC programs using manual part programming and APT techniques for manufacturing components of varying complexity. |
||
|
CO3 |
Demonstrate proficiency in the operation and basic programming of industrial robots for material handling and automated manufacturing applications. |
||
|
CO4 |
Perform machining operations on CNC lathe and CNC milling machines by applying appropriate tooling, process parameters, and safety practices to achieve specified tolerances. |
||
|
CO5 |
Simulate, validate, and optimise CNC lathe and milling operations using advanced CNC simulation software to enhance productivity, quality, and process efficiency. |
||
|
Semester No: 6th |
|
||
|
Course Title: |
Composite Materials |
Course Code: |
102609 |
|
Course Outcome No. |
Course Outcome Statement |
||
|
CO1 |
Explain the classification, properties, and applications of composite materials and their constituent fibers and matrices. |
||
|
CO2 |
Apply micromechanics and anisotropic elasticity concepts to evaluate stiffness and elastic behavior of composite lamina. |
||
|
CO3 |
Describe manufacturing processes of composite materials and select appropriate techniques for specific applications. |
||
|
CO4 |
Analyze stress–strain behavior and predict failure of laminated composites using suitable failure criteria. |
||
|
CO5 |
Analyze bending, buckling, and vibration behavior of laminated composite plates. |
||
|
Semester No: 6th |
|
||
|
Course Title: |
Power Plant Engineering |
Course Code: |
102610 |
|
Course Outcome No. |
Course Outcome Statement |
||
|
CO1 |
Explain the working, components, and subsystems of coal-based thermal power plants. |
||
|
CO2 |
Analyze gas turbine and combined cycle power plants using the Brayton cycle. |
||
|
CO3 |
Describe nuclear power plants, reactor types, and safety systems. |
||
|
CO4 |
Explain the working and performance of hydroelectric and renewable energy power plants. |
||
|
CO5 |
Analyze energy economics, environmental impacts, and sustainability aspects of power generation systems. |
||
|
Semester No: 6th |
|
||
|
Course Title: |
Renewable Energy Systems |
Course Code: |
102611 |
|
Course Outcome No. |
Course Outcome Statement |
||
|
CO1 |
Explain the concepts of renewable energy resources, sustainability, and relate their role to meet in global energy demands. |
||
|
CO2 |
Analyze solar radiation characteristics and assess the performance of solar thermal systems. |
||
|
CO3 |
Apply photovoltaic principles to analyze the construction, working, and performance improvement methods of solar PV systems. |
||
|
CO4 |
Analyse the hydropower generation as well as wind energy resources for the power extraction its performance characteristics. |
||
|
CO5 |
Explain biomass and biofuel energy conversion processes and analyze their suitability for sustainable energy generation. |
||
|
Semester No: 7th |
|
||
|
Course Title: |
Internal Combustion Engines |
Course Code: |
102701 |
|
Course Outcome No. |
Course Outcome Statement |
||
|
CO1 |
Explain the terminology, components, classification, working principles, valve timing diagrams, and ideal cycles of internal combustion engines. |
||
|
CO2 |
Apply engine performance testing methods to determine power, efficiencies, and performance parameters of IC engines. |
||
|
CO3 |
Analyse combustion processes in SI and CI engines, including knocking, detonation, and factors affecting combustion. |
||
|
CO4 |
Apply knowledge of fuel supply, ignition, lubrication, and cooling systems for appropriate IC engine applications. |
||
|
CO5 |
Analyse IC engine testing data to evaluate efficiencies, emissions, heat balance, and advanced IC engine concepts. |
||
|
Semester No: 7th |
|
||
|
Course Title: |
Internal Combustion Engines |
Course Code: |
102701P |
|
Course Outcome No. |
Course Outcome Statement |
||
|
CO1 |
Explain the terminology, components, classification, working principles, valve timing diagrams, and ideal cycles of internal combustion engines. |
||
|
CO2 |
Apply engine performance testing methods to determine power, efficiencies, and performance parameters of IC engines. |
||
|
CO3 |
Analyze combustion processes in SI and CI engines including knocking, detonation, and factors affecting combustion. |
||
|
CO4 |
Apply knowledge of fuel supply, ignition, lubrication, and cooling systems for appropriate IC engine applications. |
||
|
CO5 |
Analyze IC engine testing data to evaluate efficiencies, emissions, heat balance, and advanced IC engine concepts. |
||
|
Semester No: 7th |
|
||
|
Course Title: |
Refrigeration And Air Conditioning |
Course Code: |
102702 |
|
Course Outcome No. |
Course Outcome Statement |
||
|
CO1 |
Explain the principles, working cycles, and applications of refrigeration systems including air refrigeration (Bell–Coleman cycle), vapour compression, and vapour absorption systems. |
||
|
CO2 |
Analyze the performance of vapour compression and vapour absorption refrigeration systems considering refrigerants, subcooling, superheating, multistage compression, and modified systems such as Electrolux refrigerators. |
||
|
CO3 |
Identify, classify, and compare special refrigeration techniques including cascade, vortex, thermoelectric, steam jet refrigeration systems, and evaluate refrigerant properties, selection criteria, and leakage detection methods. |
||
|
CO4 |
Implement psychrometric principles and chart analysis to evaluate air-conditioning processes including humidity control, evaporative cooling, heating and cooling load estimation, and comfort air-conditioning requirements. |
||
|
CO5 |
Explain enthalpy potential and analyze the working and performance of air-conditioning components such as air washers, cooling towers, evaporative condensers, and cooling/dehumidifying coils. |
||
|
Semester No: 7th |
|
||
|
Course Title: |
Automobile Engineering |
Course Code: |
102705 |
|
Course Outcome No. |
Course Outcome Statement |
||
|
CO1 |
Explain the construction, layout, and working principles of automobiles and IC engines. |
||
|
CO2 |
Analyze engine auxiliary systems and emission control systems. |
||
|
CO3 |
Illustrate transmission systems, clutches, gearboxes, and drive mechanisms. |
||
|
CO4 |
Describe steering, suspension, axles, and braking systems for vehicle safety and performance. |
||
|
CO5 |
Evaluate alternative fuels and advanced automotive technologies. |
||
|
Semester No: 7th |
|
||
|
Course Title: |
Operations Research |
Course Code: |
102706 |
|
Course Outcome No. |
Course Outcome Statement |
||
|
CO1 |
Explain the fundamentals, methodology, scope, and applications of Operations Research in engineering decision-making. |
||
|
CO2 |
Formulate and solve inventory and linear programming problems using analytical and graphical/simplex methods. |
||
|
CO3 |
Solve transportation, assignment, and sequencing problems using appropriate optimization techniques. |
||
|
CO4 |
Apply network models such as PERT and CPM for project planning, scheduling, time–cost trade-off, and resource management. |
||
|
CO5 |
Analyze complex systems using dynamic programming, simulation, queuing theory, and replacement models for optimal decision-making. |
||
|
Semester No: 7th |
|
||
|
Course Title: |
Summer Entrepreneurship-III |
Course Code: |
100702P |
|
Course Outcome No. |
Course Outcome Statement |
||
|
CO1 |
To provide industrial exposure to student to apply theoretical knowledge and technical skills acquired in the classroom to solve real-world problems and execute tasks within a professional environment. |
||
|
CO2 |
To develop and refine oral and written communication skills through communicate complex ideas effectively through professional channels, oral presentations, technical documentation, internship report and attending interview and viva voce. |
||
|
CO3 |
To get exposure to team-work, leadership quality and the ability to work productively within a multidisciplinary team. |
||
|
CO4 |
To identify and adhere to the ethical standards, legal regulations, and professional codes of conduct specific to the industry. |
||
|
Semester No: 7th |
|
||
|
Course Title: |
Project-I |
Course Code: |
100709P |
|
Course Outcome No. |
Course Outcome Statement |
||
|
CO1 |
Identify and analyze a real-world engineering problem by reviewing literature, defining objectives, constraints, and performance criteria. |
||
|
CO2 |
Design and develop an engineering solution or system using appropriate mechanical engineering principles, tools, and standards. |
||
|
CO3 |
Apply experimental, analytical, or computational methods to investigate the designed solution and interpret the results. |
||
|
CO4 |
Develop and validate a functional model, prototype, or simulation that demonstrates the feasibility of the proposed solution. |
||
|
CO5 |
Evaluate the technical, economic, environmental, and societal impact of the project outcomes with reference to sustainability and ethics. |
||
|
CO6 |
Prepare professional technical reports and deliver effective oral presentations demonstrating teamwork and project management skills. |
||
|
Semester No: 8th |
|
||
|
Course Title: |
Energy Conservation and Management |
Course Code: |
102804 |
|
Course Outcome No. |
Course Outcome Statement |
||
|
CO1 |
Interpret global and national energy scenarios and evaluate environmental issues arising from energy utilisation. |
||
|
CO2 |
Assess electrical energy systems, including billing practices, transformers, motors, lighting, and power factor improvement for efficient energy use. |
||
|
CO3 |
Evaluate the performance of thermal systems such as boilers, furnaces, steam networks, and insulation to identify energy conservation measures. |
||
|
CO4 |
Analyse energy use and conservation opportunities in industrial utilities, including pumps, compressors, HVAC systems, cooling towers, and DG sets. |
||
|
CO5 |
Perform energy audits and apply energy economics techniques to recommend technically and economically viable energy conservation solutions. |
||
|
Semester No: 8th |
|
||
|
Course Title: |
Gas Dynamics and Jet Propulsion |
Course Code: |
102805 |
|
Course Outcome No. |
Course Outcome Statement |
||
|
CO1 |
Analyze the principles of compressible isentropic flow and evaluate flow behaviour in nozzles and diffusers under subsonic and supersonic conditions. |
||
|
CO2 |
Analyze non-isentropic compressible flows including Rayleigh flow, Fanno flow, and normal and oblique shock waves using governing relations. |
||
|
CO3 |
Apply the principles of jet propulsion to analyze thrust, efficiency, and performance of air-breathing engines. |
||
|
CO4 |
Explain the theory of rocket propulsion and analyze the performance characteristics of rocket engines, propellants, and staging for space applications |
||
|
Semester No: 8th |
|
||
|
Course Title: |
Safety Management |
Course Code: |
102807 |
|
Course Outcome No. |
Course Outcome Statement |
||
|
CO1 |
Explain modern safety concepts, safety management principles, and OSHA norms applicable to industrial environments. |
||
|
CO2 |
Analyze safety management functions and evaluate accident costs using system safety analysis techniques. |
||
|
CO3 |
Identify and assess industrial hazards such as pressure, fire, and electrical hazards and propose appropriate control measures. |
||
|
CO4 |
Examine hazards in construction and mechanical systems, including falls, acceleration, heat, and temperature-related risks, to ensure safe operations. |
||
|
CO5 |
Apply safe work practices, personal protective equipment (PPE), and ergonomic principles to improve workplace safety and reduce occupational risks. |
||
|
Semester No: 8th |
|
||
|
Course Title: |
Non-Conventional Manufacturing |
Course Code: |
102808 |
|
Course Outcome No. |
Course Outcome Statement |
||
|
CO1 |
Explain the classification, principles, and comparative advantages of non-conventional manufacturing processes. |
||
|
CO2 |
Describe the working principles and applications of mechanical non-traditional machining processes such as ultrasonic machining and water jet machining. |
||
|
CO3 |
Explain thermal and chemical machining processes including EDM and ECM, and analyze their suitability for specific manufacturing applications. |
||
|
CO4 |
Describe the principles, working, and applications of non-conventional welding and joining processes such as laser beam, electron beam, plasma arc, and explosive welding. |
||
|
CO5 |
Explain high-energy forming processes and micro-manufacturing fundamentals, including their applications in advanced and precision manufacturing. |
||
|
Semester No: 8th |
|
||
|
Course Title: |
Project-II |
Course Code: |
100801P |
|
Course Outcome No. |
Course Outcome Statement |
||
|
CO1 |
Identify and analyze a real-world engineering problem by reviewing literature, defining objectives, constraints, and performance criteria. |
||
|
CO2 |
Design and develop an engineering solution or system using appropriate mechanical engineering principles, tools, and standards. |
||
|
CO3 |
Apply experimental, analytical, or computational methods to investigate the designed solution and interpret the results. |
||
|
CO4 |
Develop and validate a functional model, prototype, or simulation that demonstrates the feasibility of the proposed solution. |
||
|
CO5 |
Evaluate the technical, economic, environmental, and societal impact of the project outcomes with reference to sustainability and ethics. |
||
|
CO6 |
Prepare professional technical reports and deliver effective oral presentations demonstrating teamwork and project management skills. |
||