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LESSON PLANS

II B.Tech. (Mechanical Engineering)

Instruction Schedule

I Semester: 12-06-2017 to 11-10-2017

VISION AND MISSION OF THE INSTITUTE

VISION:

To be among the Top 20 Private Engineering Institutes in India by 2020

MISSION:

Design and implement curriculum that equips students with professional and life skills.

Recruit, develop and retain outstanding faculty to achieve academic excellence

Promote and undertake quality research in thrust areas of science and Technology

Collaborate with industry and academia to meet the changing needs of society

Foster innovation and cultivate the spirit of entrepreneurship among students

VISION AND MISSION OF THE DEPARTMENT

VISION:

To create outstanding mechanical engineers who are innovative and

entrepreneurial

MISSION:

Deliver a comprehensive, industry-responsive curriculum and prepare students as prospective leaders in industry, business and academia

Develop linkages with world class research organizations and educational institutions in India and abroad for excellence in teaching, research and consultancy practices

Build a strong technical workforce that would bridge the gap between industry requirements and academic orientation

Induce entrepreneurial skills among students for contributing to the economic development of the nation

PROGRAM EDUCATIONAL OBJECTIVES

Within a few years of earning the degree in mechanical engineering, graduates are expected to achieve one or more of the following program educational objectives: I. Provide students with a sound foundation in the mathematical, scientific

and engineering fundamentals necessary to formulate, solve, and analyze engineering problems.

II. Develop successful careers as mechanical engineers; demonstrate

professional engineering competence via positions of increasing responsibility.

III. Prepare graduates to pursue higher education in engineering or other

professional fields and/or pursue entrepreneurial endeavors. IV. Participate in research and development, consultancy and other innovative

efforts in science, engineering and technology. V. Build a strong technical workforce to address social, technical and business

challenges through collaboration with industry and academia

Program Outcomes and Program Specific Outcomes

Program Outcome (PO) 1: Engineering knowledge: Apply the knowledge of mathematics, science, engineering fundamentals, and an engineering specialization for the solution of complex engineering problems. Program Outcome (PO) 2: Problem analysis: Identify, formulate, research literature, and analyze complex engineering problems reaching substantiated conclusions using first principles of mathematics, natural sciences, and engineering sciences. Program Outcome (PO) 3: Design/Development of Solutions: Design solutions for complex engineering problems and design system components or processes that meet the specified needs with appropriate consideration for public health and safety, and cultural, societal, and environmental considerations. Program Outcome (PO) 4: Conduct investigations of complex problems: Use research-based knowledge and research methods including design of experiments, analysis and interpretation of data, and synthesis of the information to provide valid conclusions.

Program Outcome (PO) 5: Modern tool usage: Create, select, and apply appropriate techniques, resources, and modern engineering and IT tools including prediction and modeling to complex engineering activities with an understanding of the limitations. Program Outcome (PO) 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 to the professional engineering practice. Program Outcome (PO) 7: Environment and sustainability: Understand the impact of the professional engineering solutions in societal and environmental contexts, and demonstrate the knowledge of, and need for sustainable development. Program Outcome (PO) 8: Ethics: Apply ethical principles and commit to professional ethics and responsibilities and norms of the engineering practice. Program Outcome (PO) 9: Individual and team work: Function effectively as an individual, and as a member or leader in diverse teams, and in multidisciplinary settings. Program Outcome (PO) 10: Communication: Communicate effectively on complex engineering activities with the engineering community and with t h e society at large, such as, being able to comprehend and write effective reports and design documentation, make effective presentations, and give and receive clear instructions Program Outcome (PO) 11: Project management and finance: Demonstrate knowledge and understanding of the engineering 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. Program Outcome (PO) 12: Life-long learning: Recognize the need for, and have the preparation and ability to engage in independent and life-long learning in the broadest context of technological change. Program Outcome (PO) 13: Program Specific Outcome: Function effectively in Industry or as entrepreneurs to solve inter disciplinary problems. Program Outcome (PO) 14: Program Specific Outcome: Demonstrate knowledge and understanding of thermal, structural and manufacturing streams of Mechanical Engineering.

FOREWARD

The LESSON PLANS are prepared and

distributed to the students to help them maintain proper

time schedules, attend classes regularly for better

understanding of the course and to face the

examinations with confidence. The lesson plans also

help students to be up-to-date by keeping track of the

syllabus covered. Students should attend classes

regularly for continuity and prepare their own study

notes for every course.

P R I N C I P A L

Academic Calendar for the Academic Year 2017-18

I Semester

S. No. Description Schedule Duration

1 Commencement of Class work 12.06.2017 --

2 1st Spell of Instruction 12.06.2017 to 05.08.2017 8 Weeks

3

1st Mid Examinations

Timings: FN: 10.00 am to 11.30 am : AN:2.00 pm to 3.30 pm

08.08.2017 to 10.08.2017 3 Days

4 2nd Spell of Instruction (Includes Dasara Holidays) 11.08.2017 to 11.10.2017 9 Weeks

6 2nd Mid Examinations Timings: FN: 10.00 am to 11.30 am : AN:2.00 pm to 3.30 pm

12.10.2017 to 16.10.2017 3 Days

7 End Semester Regular Examinations / Supplementary Examinations (Theory & Practical)

17.10.2017 to 02.12.2017 7 Weeks

8 Commencement of Class work for II, III, IV B.Tech. II Sem. for the academic year 2016-2017

04.12.2017 --

II Semester

S. No. Description Schedule Duration

1 Commencement of Class work 04.12.2017 --

2 1st Spell of Instruction 04.12.2017 to 27.01.2018 8 Weeks

3 1st Mid Examinations Timings: FN: 10.00 am to 11.30 am : AN:2.00 pm to 3.30 pm

29.01.2018 to 31.01.2018 3 Days

4 2nd Spell of Instruction 01.02.2018 to 28.03.2018 8 Weeks

5 2nd Mid Examinations

Timings: FN: 10.00 am to 11.30 am : AN:2.00 pm to 3.30 pm

29.03.2018 to 31.03.2018 3 Days

6 End Semester Regular Examinations / Supplementary Examinations (Theory & Practical)

02.04.2018 to 19.05.2018 7 Weeks

7 Commencement of Class work for II, III, IV B.Tech. I Sem. for the academic year 2018-2019

11.06.2018 --

Academic Year: 2017-18 II B.Tech. I Sem

COURSE STRUCTURE:: B-TECH- (MECHANICAL ENGINEERING)

II Year I Semester

S.No. Course Code Course

Hours/Week Marks L T P/D C CIE SEE Total

1 HS104 Economics and Finance for Engineers 3 - - 3 30 70 100

2 BS106 Environmental Studies 3 - - 3 50 50 100

3 BS109 Mathematics – II 3 - - 3 30 70 100

4 ES118 Thermodynamics 4 - - 4 30 70 100

5 ES119 Mechanics of Solids 3 1 - 3 30 70 100

6 ME101 Metallurgy and Material Science 4 - - 4 30 70 100

7 ME105 Mechanics of Solids and Metallurgy Lab - - 3 2 30 70 100

8 ME106 Technical Sketching and Computer Aided Modelling - - 3 2 30 70 100

9 MC101 Business Communication and Public Speaking 1 - 1 - - - -

Total 24 260 540 800

II Year II Semester

S.No. Course Code Course

Hours/Week Marks L T P/D C CIE SEE Total

1 HS105 Engineering Ethics 2 - - 2 30 70 100

2 BS110 Probability and Statistics 3 - - 3 30 70 100

3 ES112 Foundations to Product Design 3 - - 3 50 50 100

4 ME102 Applied Thermodynamics 4 1 - 4 30 70 100

5 ME103 Production Technology 4 - - 4 30 70 100

6 ME104 Theory of Machines 4 1 - 4 30 70 100

7 ME107 Applied Thermodynamics Lab - - 3 2 30 70 100

8 ME108 Production Technology Lab - - 3 2 30 70 100

9 MC102 Gender Sensitization - - 2 - - - -

Total 24 260 540 800


(HS104) ECONOMICS AND FINANCE FOR ENGINEERS

COURSE OBJECTIVES: The objectives of the course are 1. Explain importance of Economics and its application into business practice. 2. Develop least cost combination of inputs in production 3. Formulate suitable pricing policy pricing method 4. Apply the concepts of Accounting in calculating the profits of business 5. Identify relevant Capital budgeting techniques and appraise the projects. COURSE OUTCOMES: The students will be able to 1. Forecast the demand for product / service for a profitable Business administration. 2. Apply the demand forecasting techniques to estimate the demand 3. Minimize the cost incurred in Production and estimate the profit zone. 4. Recognize the time value in cash flows 5. Evaluate various investment opportunities and select best project 6. Develop least cost combination of inputs in production 7. Analyze Capital Budgeting techniques. 8. Build Financial Reports and evaluate financial status of the organization.

LESSON PLAN

Name of the Faculty: M.Rajyalaxmi Academic Year: 2017 - 18 Course Number : ME101 Course Name: EFE Program : B.Tech. Branch: ME Year / Semester : II / I

S. No. Topic Schedule Date

1 UNIT - I: Introduction to Managerial Economics - Introduction

12/06/17

2 Nature and Scope of managerial economics. 14/06/17

3 Demand analysis - Law of consumption. 14/06/17

4 Law of marginal, utility and exceptions 15/06/17

5 Indifference centre - properties. 19/06/17

6 Law of demand and its determinations - 21/06/17

7 Exceptions to Law of demand. 22/06/17

8 Definition and types of elasticity of demand. 28/06/17

9 Measurement and significance of ED 29/06/17

10 Demand forecasting - Factors. 3/07/17

11 Demand forecasting - Factors. 5/07/17

12 Methods of demand forecasting. 12/07/17

13 Methods of demand forecasting. 13/07/17


14 UNIT - II: Theory of Production and Cost Analysis-Introduction

17/07/17

15 Production function-with one variable inputs 19/07/17

16 Production function-with two and multi variable inputs 20/07/17

17 Cobb-douglas production function. 24/07/17

18 Isoquants and properties 24/07/17

19 Isocost - Properties. 26/07/17

20 Marginal rate of technical substitution. 26/07/17

21 Least cost combination of input. 27/07/17

22 Cobb-douglas production function. 27/07/17

23 Laws of returns. 31/07/17

24 Internal & External economies of scale. 31/07/17

25 Cost concepts. 31/07/17

26 Break-even analysis and it limitations. 2/08/17

27 Determination of break even analysis - problems. 2/08/17

28 Application of BEA 2/08/17

29 UNIT-III Introduction to Markets and Pricing Policies-Introduction

2/08/17

30 Markets meaning, types, characteristics 3/08/17

31 Perfect Competition-characteristics 3/08/17

32 I Mid Exams 8/08/17 - 10/08/17

33 Competition-Price output determination 16/08/17

34 Monopolistic Market its Features 17/08/17

35 Monopoly Market characteristics 21/08/17

36 Price-output determination - monopoly. 23/08/17

Price Discrimination, Basis and advantages 24/08/17

37 Perfect Competition V/s Monopoly 28/08/17

38 Pricing objectives, policies. 30/08/17

39 Pricing methods 31/08/17

40 Pricing strategies in Times of Stiff Price Competition 4/09/17

41 UNIT - IV: Introduction to Financial Accounting: 6/09/17

42 Book Keeping-Accounting, Accounting Cycle, Accounting Concepts and Conventions

6/09/17

43 Double Entry Rules 7/09/17

44 Journal 11/09/17


45 Ledger 13/09/17

46 Trial balance. 14/09/17

47 Capital V/s Revenue Items 18/09/17

48 Financial accounts - problems. 20/09/17

49 Ratios- Introduction 20/09/17

50 Liquidity ratios. 21/09/17

51 Activity ratios. 21/09/17

52 Capital structure ratios. 25/09/17

53 Profitability ratios. 4/10/17

54 UNIT -V Capital and Capital Budgeting - Introduction 6/10/17

55 Estimation of fixed and working capital 6/10/17

56 Methods and sources of finance. . Nature and scope of capital budgeting.

9/10/17

57 Methods of capital budgeting 9/10/17

58 Pay back method - problems. 11/10/17

59 Average Rate of Return Method - Problems 11/10/17

60 Net present value method - problems. 11/10/17

Time Table:

Monday : 9:30 - 10:20 Thursday : 3:15 - 4:00

Tuesday : Friday :

Wednesday : 11:20 - 12:10 Saturday :


(BS106) ENVIRONMENTAL STUDIES

COURSE OBJECTIVES: Students will be able to 1. Recall the importance of environment and its related issues. 2. Discuss about biogeochemical cycles and biodiversity. 3. Predict threats to the flora and fauna of biodiversity. 4. Evaluate environmental impact, its prediction methods. 5. Create awareness towards global environmental issues, population growth, and use of

energy resources, sustainability and waste management. COURSE OUTCOMES: At the end of the course, the students will develop ability to 1. Memorize the concept of environment and its related issues. 2. Paraphrase about components of ecosystem and environment cycles. 3. Compute loss of biodiversity. 4. Categorize the values and conservation of biodiversity. 5. Prioritize energy resources, sustainability, pollution and its types. 6. Estimate global environmental issues and waste management. 7. Recommend solutions to population growth, natural disasters and waste management. 8. Formulate the impacts of environment and its assessment.

LESSON PLAN

Name of the Faculty : Dr. E.SAROJA Academic Year: 2017 - 2018 Course Number : BS106 Course Name : Environmental Studies Program : B.Tech Branch : ME Year / Semester : II / I

S. No. Topic Schedule Date

1. Introduction to Environmental Studies. 12|06/2017

2. Multidisciplinary nature of Environmental Studies 14/06/2017

3. Concept of ecosystem: Introduction, Types of ecosystems- forest and aquatic ecosystems-lentic (pond), lotic ( river) and estuaries

17/06/2017

4. Structure-Biotic (Producers, Consumers and Decomposers) and Abiotic 17/06/2017

5. Functions-energy flow in an ecosyst 21/06/201

6. hain- significance (bio magnification-pest & pest control-case study-DDT, Arsenicosis Disease), 24/06/2017

7. Food web, Ecological Pyramids-Pyramids of Energy, pyramids of number and pyramids of biomass 24/06/2017

8. Bio-geo Chemical Cycles- Hydrological Cycle, Carbon Cycle 28/06/2017

9. Nitrogen Cycle 01/07/2017

10. Evolution in the ecosystem: Ecological succession-xerosere and hydrosere. 01/07/2017

11. Discussion on field work 01/07/2017


Unit-II Biodiversity and Its Conservation

12. Definition, types 03/07/2017

13. Values-productive use, consumptive use, social value, ethical value, aesthetic value and option value 05/07/2017

14. Biodiversity vs bio productivity, biodiversity vs biotechnology 12/07/2017

15. Threats to biodiversity: Habitat loss, 14/07/2017

16. Poaching of wildlife, Invasive species(Exotic), 14/07/2017

17. List of endangered and endemic species, 17/07/2017

18. Conservation of biodiversity- In situ and Ex situ. 19/07/2017


20. Presentations on field work 22/07/2017



Unit-III Renewable Energy

23. Energy resources-Growing energy needs, Renewable-Solar energy, hydroelectric power, wind energy 29/07/2017

24. Bio-energy (bio-ethanol, methane, hydrogen) 29/07/2017

25. Tidal energy and geothermal energy 31/07/2017

26. Sustainable development

27. Sustainability-concept, threats to sustainability, 02/08/2017

28. Strategies for achieving sustainability, green building concept. 05/08/2017

I - Internal Examination 08/08/2017to 10/08/2017

29. Population growth and Its Consequences

30. Population- Health Consequences, 07/08/2017

31. Population growth in rich & poor nations-their problems, 16/08/2017

32. Demographic transition. 19/08/2017


Unit-IV Pollution

34. Pollution-Introduction, Types- air and water – causes, effects and Control measures

21/08/2017

35. Air pollution sampling techniques, 23/08/2017

36. Aerobic and anaerobic (treatment of sludge process – composting pasteurization), 26/08/2017

37. Alternate treatment systems-septic system 26/08/2017

38. Composting septic system


30/08/2017

Global Environmental Issues

39. Urban environmental problems, 04/09/2017

40. Global warming (Climate change- Carbon sequestration- Plants, soil and oceans, green house gases), 06/09/2017

41. Acid rain, Ozone layer depletion and Bio fuels vs. Food crisis, 11/09/2017

42. Disasters- Fukushima Daiichi nuclear disaster, The Jilin Chemical Explosion. 13/09/2017

43. Ganga action plan, Protocols-Kyoto and Montreal. 16/09/2017


Unit-V Waste Management

45. Wealth from the Waste- fly ash, 18/09/2017

46. Solid waste treatment methods-Composing, vermicomposting, 23/09/2017

47. Incineration, pyrolysis, autoclaving, land filling and recycling. 23/09/2017

48. Collection, handling rules and segregation of municipal solid waste 23/09/2017

49. Bio-medical waste and e-waste 25/09/2017

Environmental Impact Assessment (EIA)

50. EIA-Definition, Impact-Classification of impacts (positive and negative) 27/09/2017

51. Prediction methods of EIA- adhoc and matrix method 27/09/2017






II - Internal Examination 12/10/2017 to 14/10/2017

Time Table:

Monday : Thursday : 3:15 - 4:00

Tuesday : Friday : Wednesday : 1:40 - 2:30 Saturday : 11:20 – 01:00


(BS109) MATHEMATICS – II

COURSE OBJECTIVES: Students will be able to 1. Identify Laplace and inverse Laplace transforms with applications. 2. Illustrate Fourier series expansion. 3. Compute vector differentiation and integration. 4. Evaluate complex integration and applications. 5. Calculate residues and contour integration. COURSE OUTCOMES: At the end of the course, the students will be develop ability to 1. Explain Laplace transforms to solve differential equations. 2. Decide Laplace transform technique to engineering problems. 3. Recommend vector calculus to different engineering problems. 4. Discuss analitical functions apply to velocity potentials, stream functions, orthogonal

trajectories. 5. Create complex integration to solve real improper integrals. 6. ApplyFourier series to engineering problems. 7. Analyze vector integral theorems. 8. Judge in evaluation of contour integration.

LESSON PLAN

Name of the Faculty: G.ANUSHA Academic Year: 2017 - 2018 Course Number : BS109 Course Name : M-II Program : B-Tech Branch : ME Year / Semester : II / I Section :

S.No. Topic Schedule Date

UNIT- I

1 Definition and Laplace transforms of standard functions 12/06/2017

2 Finding Laplace Transform of given functions 13/06/2017

3 First & Second Shifting theorems in Laplace transform 16/06/2017

4 Change of scale property in Laplace transform 16/06/2017

5 Laplace transform of Derivatives & Integrals 17/06/2017

6 Laplace transform of functions multiplied by t & divided by t 19/06/2017

7 Laplace transform of Periodic functions 20/06/2017

8 Introduction to inverse Laplace transform & problems 23/06/2017

9 First & Second Shifting theorems in inverse Laplace transform 24/06/2017

10 Change of scale property in inverse Laplace transform 30/06/2017

11 Inverse Laplace transforms of Derivatives & Integrals 30/06/2017

12 Inverse Laplace transforms of functions multiplied by s & divided by s

1/07/2017 3/07/2017

13 Convolution theorem (with out proof ) 4/07/2017


14 Applications of Laplace transforms to Ordinary Differential equations

7/07/2017 7/07/2017

UNIT – II

15 Definition of Fourier series and Dirichlet conditions 11/07/2017

16 Fourier series of functions defined in [C, C+2π] 14/07/2017

17 Fourier series of even and odd functions 14/07/2017

18 Half range Fourier Sine and Cosine series 17/07/2017

19 Fourier series in arbitrary intervals [C, C+2L] 18/07/2017

20 Fourier series of even and odd functions in [0, 2L] 21/07/2017

21 Half range Fourier – Sine and Cosine series in [0,L] 21/07/2017

22 Definition of Fourier series and Dirichlet conditions 22/07/2017

23 Fourier series of functions defined in [C, C+2π] 24/07/2017

24 Fourier series of even and odd functions 25/07/2017

25 Half range Fourier Sine and Cosine series 28/07/2017

26 Fourier series in arbitrary intervals [C, C+2L] 28/07/2017

27 Fourier series of even and odd functions in [0, 2L] 29/07/2017

28 Half range Fourier – Sine and Cosine series in [0,L] 31/072017, 1/08/2017

UNIT – III

29 Introduction to vector differentiation 4/08/2017

30 Gradient of a scalar function 4/08/2017

31 Divergence of vector function 5/08/2017

32 Curl of a vector function 7/08/2017

I-MID EXAMINATION 8/08/2017

TO 10/08/2017

33 Vector identities (without proofs) 11/08/2017

34 Introduction to Vector Integration 11/08/2017

35 Line integrals 18/08/2017

36 Surface integrals 18/08/2017

37 Volume integrals 19/08/2017

38 Vector Integral Theorems – Green’s theorem and problems 21/08/2017

39 Stokes theorem and problems 22/09/2017, 25/08/2017

UNIT-IV

40 Continuity, Differentiability 26/08/2017

41 Analytic function – properties 28/08/2017


42 Cauchy – Riemann conditions, problems 29/08/2017

43 Harmonic function – conjugate 1/09/2017

44 Milne – Thompson method 2/09/2017

45 Line integral 4/09/2017 8/09/2017

46 Cauchy integral theorem and problems 8/09/2017

47 Cauchy integral formula, generalization, problems 11/09/2017 12/09/2017

48 Radius of convergence, Taylor’s, Maclaurin’s series expansion 15/09/2017 16/09/2017

49 Laurent series, problems 18/09/2017 19/09/2017

50 Types of singularities, problems 22/09/2017

UNIT- V

51 Residue – Evaluation 23/09/2017 25/09/2017

52 Residue Theorem – problems 26/09/2017 , 3/10/2017

53 Evaluations of improper real integrals (4 types) 6/10/2017 7/10-2017

54 Problems 9/10/2017 10/10/2017

II - Mid Examination

12/10/2017 13/10/2017

& 16/10/2017

Time Table:

Monday : 12:10 - 01:00 Thursday :

Tuesday : 9:30 - 10:20 Friday : 1:40 - 3:15

Wednesday : 9:30 - 10:20 Saturday :


(ES118) THERMODYNAMICS

COURSE OBJECTIVES: 1. Discuss the basic principles of thermodynamics. 2. Illustrate various thermodynamic properties like internal energy, enthalpy, entropy,

temperature, pressure, specific volume. 3. State the properties of pure substance. 4. Explain the laws of perfect gases. 5. Classify various thermodynamic cycles COURSE OUTCOMES: The students will be able to 1. Explain the basic thermodynamics principles and their applications 2. Summarize various thermodynamic properties. 3. Apply the laws of thermodynamics to analyze boilers, heat pumps, refrigerators, heat

engines, compressors and nozzles. 4. Calculate the available energy and irreversibility. 5. Evaluate entropy changes in a wide range of processes 6. Illustrate the properties of pure substances. 7. Apply psychometric chart to find out various psychometric properties. 8. Analyze various thermodynamic cycles.

LESSON PLAN

Name of the Faculty: DHEERAJ JOSHI Academic Year: 2017 - 2018 Course Number : ES118 Course Name : Thermodynamics Program : B-Tech Branch : ME Year / Semester : II / I


UNIT- I

1 Basic concepts: system surrounding, control volume, boundaries, universe, types of systems, macroscopic microscopic view points, concept of continuum

12/06/2017

2 Thermodynamic equilibrium, state, property, process, cycle, quasi-static process 12/06/2017

3 Reversible, irreversible process, causes of irreversibility 14/06/2017

4 Zeroth law of thermodynamics ,concept of quality of temperature, principles of thermometry 15/06/2017

5 Reference points, constant volume gas thermometers, scales of temperature, ideal gas scale 16/06/2017

6 Energy, heat, specific heat 19/06/2017

7 Work, forms of work transfer 19/06/2017

8 expression of work for different processes in closed system 21/06/2017

9 Expression of work for different processes in open system 22/06/2017

10 Problems Solving 23/06/2017




13 Revision 30/06/2017

UNIT - II

15 First law of thermodynamics 03/07/2017

16 Joules experiment 03/07/2017

17 1st law applied to a process 05/07/2017

18 Applied to flow system 06/07/2017

19 Steady flow energy equation, PMM1 07/07/2017

20 Second law of thermodynamics 12/07/2017

21 Heat engine heat pump 13/07/2017

22 Refrigerator parameters of performance 14/07/2017

23 Kelvin plank and clausius statements and their corollaries 17/07/2017

24 PMM2 , carnot principle, carnot cycle and its specialties 17/07/2017

25 Entropy, clausius inequality, principle of entropy increase 19/07/2017

26 Availability and irreversibility 20/07/2017

27 Thermodynamic potential, gibbs and Helmholtz function, Maxwell relation, Elementary treatment of third law of thermodynamics

21/07/2017



UNIT – III

30 Pure substance: Introduction p-v-t surfaces 26/07/2017

31 T-S and H-S diagram, mollier charts 27/07/2017

32 Phase transformation triple point at critical state properties during change of phase 28/07/2017

33 Dryness fraction 31/07/2017

34 Clausius clapeyron equation 31/07/2017

35 Various thermodynamics processes and energy transfer 02/08/2017

36 Steam calorimetry 03/08/2017

37 Perfect gas laws: equation of state 04/08/2017

38 Specific and universal gas constants 07/08/2017

39 Various non flow processes properties and end states 07/08/2017

I- Mid Examination 08/08/2017 to 10/08/2017

40 Flow processes, deviation from perfect gas model 11/08/2017

41 Vanderwall equation , compressibility charts, gas tables 16/08/2017

UNIT – IV


42 Mixture of perfect gases: Introduction Terminology 17/08/2017

43 Mass fraction gravimetric and volumetric analysis 18/08/2017

44 Dalton law of partial pressure 21/08/2017

45 Avogadro’s law of additive volumes-mole fraction, volume fraction, partial pressure 21/08/2017

46 Equivalent gas constants and molecular internal energy 23/08/2017

47 Enthalpy ,sp heats and entropy of mixture of perfect gases and vapour 24/08/2017

48 Problems 28/08/2017

49 Psychrometry: Introduction 28/08/2017

50 Atmospheric air, psychrometric properties 30/08/2017

51 Dry bulb temperature, wet bulb temperature 31/08/2017

52 Dew point temperature, thermodynamic wet bulb temperature 01/09/2017

53 Specific humidity, relative humidity 04/09/2017

54 Saturated air, vapour pressure 04/09/2017

55 Degree of saturation, adiabatic saturation 06/09/2017

56 Carrier’s equation 07/09/2017

57 Psychometric chart 08/09/2017



UNIT- V

60 Power cycles: Introduction 13/09/2017

61 Otto cycle 14/09/2017

62 Diesel cycle 15/09/2017

63 Dual combustion cycle 18/09/2017

64 Sterling cycle 18/09/2017

65 Atkinson cycle, Ericsson cycle 21/09/2017

66 Lenior cycle 22/09/2017

67 Description and representation of P-V and T-S diagram 25/09/2017

68 Description and representation of P-V and T-S diagram 25/09/2017

69 Thermal efficiency 27/09/2017

70 Mean effective pressure on air standard basis 04/10/2017

71 Comparision of cycles 05/10/2017

72 Performance evaluation and combined cycles 06/10/2017

73 Unit I,II& III Revision 09/10/2017

74 Unit IV & V Revision 09/10/2017


75 Discussing old Question Papers 11/10/2017

II - Mid Examination 12/10/2017 to 16/10/2017

Time Table:

Monday : 10:20 – 12:10 Thursday : Tuesday : Friday : 9:30 - 10:20

Wednesday : 12:10 - 01:00 Saturday : 1:40 - 2:30


(ES119) MECHANICS OF SOLIDS

COURSE OBJECTIVES: Student will be able to 1. Classify the stresses 2. Draw the SF and BM diagrams of CB,SSB and OHB 3. Calculate the bending and shear stress 4. Explain the principal stresses and strains 5. Distinguish between thin cylinder and thick cylinder COURSE OUTCOMES: At the end of the course students develop ability to 1. Apply the mathematics 2. Recall engg mechanics basics 3. Illustrate the static determinacy 4. Draw SF and BM diagrams 5. Apply the principal stress and strain concept 6. Calculate the flexural and shear stress 7. Design the pressure vessels 8. Evaluate the deflections of CB,SSB and OHB

LESSON PLAN

Name of the Faculty : B.SATISH KUMAR Academic Year: 2017 - 18 Course Number : ES119 Course Name: MOS Program : B.Tech. Branch : ME Year / Semester : II / I S.No. Topic Schedule Date

1. UNIT – I Shear Force and Bending Moment: Definition of beam – Types of beams

14-06-2017

2. Concept of shear force and bending moment 15-06-2017

3. S.F. and B.M. diagrams for cantilever beams subjected to point loads 15-06-2017

4. S.F. and B.M. diagrams for simply supported and overhanging beams subjected to point loads 16-06-2017

5. S.F. and B.M. diagrams for u.d.l., uniformly varying loads and combination of these loads 16-06-2017

6. Points of contra flexure 21-06-2017 7. Relation between S.F., B.M. 22-06-2017

8. Rate of loading at a section of a beam. 22-06-2017

9. Rate of loading at a section of a beam. 23-06-2017 10. Revision of 1st unit 23-06-2017 11. Revision of 1st unit 28-06-2017 12. Revision of 1st unit 29-06-2017 13. Revision of 1st unit 29-06-2017

14. UNIT – II Flexural Stresses: 30-06-2017


15. Theory of simple bending 30-06-2017 16. Assumptions in simple bending 05-07-2017 17. Derivation of bending equation: M/I=f/y=E/R 06-07-2017 18. Derivation of bending equation: M/I=f/y=E/R 06-07-2017 19. Neutral axis – Determination bending stresses 07-07-2017

20. section modulus of rectangular and circular sections (Solid and Hollow) 07-07-2017

21. section modulus of rectangular and circular sections (Solid and Hollow) 12-07-2017

22. I.T.Angle and Channel sections 13-07-2017 23. Design of simple beam sections. 13-07-2017 24. Shear Stresses: Derivation of formula 14-07-2017 25. Shear stress distribution across various beams 14-07-2017

26. sections like rectangular, circular, triangular 19-07-2017

27. Shear stress distribution across I.T. angle sections 20-07-2017 28. Revision for 2nd unit 20-07-2017 29. Revision for 2nd unit 21-07-2017 30. Revision for 2nd unit 21-07-2017

31. UNIT – III Deflection of Beams: Bending into a circular arc – slope 26-07-2017

32. deflection and radius of curvature 27-07-2017 33. Differential equation for the elastic line of a beam 27-07-2017 34. Double integration 28-07-2017 35. Macaulay’s Method and moment area method 28-07-2017 36. Macaulay’s Method and moment area method 02-08-2017

37. Determination of slope and deflection for cantilever and simply supported beams subjected to point loads 03-08-2017

38. Determination of slope and deflection for cantilever and simply supported beams subjected to point loads 03-08-2017

39. Revision for Ist MID Examinations 04-08-2017

I –Mid Examinations 08-08-2017 to 10-08-2017

40. Determination of slope and deflection for cantilever and simply supported beams subjected to UDL 16-08-2017

41. combination of point load and U.D.L. 17-08-2017 combination of point load and U.D.L. 17-08-2017

42. Revision for 3rd unit 18-08-2017

43. Revision for 3rd unit 18-08-2017

44. UNIT – IV Columns and Struts: Introduction 23-08-2017

45. Classification and behavior of columns 24-08-2017 46. crippling load 24-08-2017 47. Euler’s theory of column 30-08-2017 48. crippling load for different end conditions 31-08-2017


49. Springs: Introduction 31-08-2017 50. functions of springs 06-09-2017 51. Deflection of helical compression spring under axial load. 07-09-2017 52. Deflection of helical compression spring under axial load. 07-09-2017 53. Revision for 4th unit 08-09-2017 54. Revision for 4th unit 08-09-2017 55. Revision for 4th unit 13-09-2017

56.UNIT – V Principal Stresses and Strains: axial loading – Compound Stress

14-09-2017

57. Normal and tangential stresses on an inclined plane for biaxial stress 14-09-2017

58. Two perpendicular normal stress accompanied by a state of simple shear stress 15-09-2017

59. Mohr’s stress circle method 15-09-2017 60. Thin Cylinders: Thin seamless cylindrical shells 21-09-2017

61. Derivation of formula for longitudinal and circumferential stresses 21-09-2017

62. hoop, longitudinal and volumetric strains 22-09-2017 63. changes in dia, and volume of thin cylinders 22-09-2017 64. Riveted boiler shells. 04-10-2017 65. Revision for 5th unit 05-10-2017 66. Revision for 5th unit 05-10-2017

67. Discussion on previous exam Question papers 06-10-2017



II –Mid Examinations 12-10-2017 to 16-10-2017

Time Table:

Monday : 2:30 - 3:15 Thursday : 1:40 – 03:15

Tuesday : 11:20 – 01:00 Friday :

Wednesday : Saturday :


(ME101) METALLURGY & MATERIAL SCIENCE

COURSE OBJECTIVES: 1. Describe the bond formation between grains and crystals. 2. Evaluate equilibrium diagram and lever rule in calculating the liquid and solid

percentage. 3. Analyze heat treatment process to different materials to get required properties. 4. Categorize advanced materials of composite, ceramic and metal matrix composites. 5. Discuss the behavior of non-ferrous metals and ferrous metals. COURSE OUTCOMES: The students will be able to 1. Understand the bond formation between grains and crystals. 2. Create new materials using equilibrium diagram and lever rule. 3. Perform heat treatment process to different materials to get required properties. 4. Develop advanced materials like composite, ceramic and metal matrix composites. 5. Evaluate the effect of grain boundaries on mechanical properties of metals. 6. Design required tool materials for machining steels. 7. Construction of equilibrium phase diagrams 8. Assess the preparation of nanomaterial.

LESSON PLAN

Name of the Faculty : Dr. P. SAMMAIAH Academic Year: 2017 - 18 Course Number : ME101 Course Name: MMS Program : B.Tech. Branch: ME Year / Semester : II / I


1 UNIT - I: Structure of Metals: Introduction to metallurgy and material science 12-06-2017

2 Classification of materials. 13-06-2017

3 Properties of materials. 14-06-2017

4 Bonds in solids (Ionic & Covalent) 17-06-2017

5 Metallic bond. 19-06-2017

6 Crystallization of metals. 20-06-2017

7 Bravis lattices, crystal structures. 21-06-2017

8 Grain and grain boundaries. 24-06-2017

9 Effect of grain boundaries on the properties of metal/alloys. 28-06-2017

10 Determination of grain size. 01-07-2017

11 Discussion on previous question papers and assignment questions. 03-07-2017

12 Construction of Alloys: Necessity of alloying. 04-07-2017

13 Types of solid solutions. 05-07-2017

14 Hume Rotherys rules. 08-07-2017

15 Intermediate alloy phases. 08-07-2017


16 Electron compounds. 11-07-2017


18 UNIT - II: Equilibrium of Diagrams: Methods of construction of equilibrium diagrams. 12-07-2017

19 Isomorphous alloy systems. 12-07-2017

20 Equilibrium cooling and heating of alloys. 15-07-2017

21 Lever rule, coring miscibility gaps. 15-07-2017

22 Eutectic systems. 17-07-2017

23 Congruent melting intermediate phases. 18-07-2017

24 Peritectic reaction. 19-07-2017

25 Transformations in the solid state - allotropy, eutectoid. 22-07-2017

26 Peritectoid reactions, phase rule. 22-07-2017

27 Relationship between equilibrium diagrams and properties of alloys. 24-07-2017

28 Study of important binary phae diagrams of Cu-Ni, Al-Cu. 24-07-2017

29 Bi-Cd, Cu-An. 25-07-2017

30 Fe-Fe3C Diagram 26-07-2017


32 UNIT - III: Cast irons and steels: Structure and properties of white acts iron. 01-07-2017

33 Malleable, Grey and Spheroidal graphite cast irons. 01-08-2017

34 Alloy cast irons. 02-08-2017

35 Classification of steels. 02-08-2017

36 Structure and properties of plain carbon steels. 05-08-2017

37 Low alloy steels. 12-08-2017

38 Hadfield manganese steels. 12-08-2017

39 Tool and Die-steels. 12-08-2017


41 Revision. 16-08-2017 42 Revision. 19-08-2017

43 UNIT - IV: Heat Treatment of Alloys: Effect of alloying elements on system. 21-08-2017

44 Annealing. 22-08-2017

45 Normalizing. 22-08-2017

46 Hardening. 23-08-2017

47 TTT diagrams. 26-08-2017

48 Tempering. 28-08-2017


49 Hardenability. 29-08-2017

50 Surface - hardening treatment. 30-08-2017

51 Age hardening treatment. 30-08-2017

52 Cryogenic treatment of alloys. 30-08-2017


54 Non-Ferrous Metals and Alloys: Structure and properties of copper. 04-09-2017

55 Alloys of copper. 05-09-2017

56 Aluminum and its alloys. 06-09-2017

57 Titanium and its alloys. 09-09-2017


59 UNIT - V: Ceramic Materials: Crystalline ceramics, glasses. 11-09-2017

60 Cermets, abrasive materials. 12-09-2017

61 Nanomaterials. 13-09-2017


63 Composite Materials:- Classification of composites. 16-09-2017

64 Various methods of component manufacture of composites. 19-09-2017

65 Particle - reinforced materials. 23-09-2017

66 Fiber - reinforced materials. 25-09-2017

67 Metal ceramic mixtures. 26-09-2017

68 Metal - matrix composites. 03-10-2017

69 C-C composites. 04-10-2017


71 Revision 10-10-2017

72 Revision 11-10-2017 Time Table:

Monday : 1:40 - 2:30 Thursday : Tuesday : s10:20 -11:10 Friday :

Wednesday : 9:30 – 11:10 Saturday : 10:20 -11:10


(ME105) MECHANICS OF SOLIDS AND METALLURGY LAB

COURSE OBJECTIVES: Student will be able to 1. Identify the microstructure of ferrous and non ferrous metals 2. Calculate the hardness of metals with or without heat treatment 3. Evaluate the properties of various materials 4. Compare the properties of brittle and ductile materials. 5. Choose an appropriate materials for given application

COURSE OUTCOMES: 1. Apply the mathematics 2. Recall the engineering mechanics and mechanics of solids 3. Identify grain and grain boundary, crystal structure of different materials. 4. Study the microstructure of various materials. 5. Analyze the correlation between Mechanical and Metallurgical properties. 6. Perform material testing and analyze various material properties 7. Draw stress Vs strain diagram of ductile and brittle materials. 8. Select a suitable material for given application.

LESSON PLAN

Name of the Faculty: Dr.P.Sammaiah/Dr.A.Devaraju Academic Year: 2017 - 18 Course Number : ME105 Course Name: MOS&M Lab Program : B.Tech Branch : ME Year / Semester : II/I

S.No. Topic

Schedule Date

Batch –I Batch - II

* Introduction to Mechanics of Solids and Metallurgy Lab 13-06-2017 15-06-2017

CYCLE I

1. Direct tension test & Compression test on cube 20-06-2017 22-06-2017

2. Torsion test 04-07-2017 29-01-2017

3. Hardness test

a. Rockwell hardness test b. Brinell hardness test

11-07-2017 06-07-2017

4. Test on springs 18-07-2017 13-07-2017

5. Impact test 25-07-2017 20-07-2017

I - Internal Lab Exam 01-08-2017 27-07-2017

CYCLE II

1. Preparation and study of the Microstructure of pure metals like Iron, Cu and Al 22-08-2017 03-08-2017

2. Preparation and study of the Microstructure of Mild 29-08-2017 17-08-2017


steel, Low carbon steel, high Carbon steel

3. Study of the Microstructure of Cast Irons 05-09-2017 24-08-2017

4. Study of the Microstructure of Non-Ferrous alloys 12-09-2017 31-08-2017

5. Study of the Microstructure of Heat treated steels 19-09-2017 07-09-2017

6. To find out the hardness of heat treated and un-heat treated Mild steel 26-09-2017 14-09-2017

7. Hardenability of steel by Jominy End Quench Test 03-10-2017 21-09-2017

II - Internal Lab Exam 10-10-2017 05-10-2017

Time Table:

Monday : Thursday : 10:20 – 01:00

Tuesday : 01:40 – 04:00 Friday : Wednesday : Saturday :


(ME106) TECHNICAL SKETCHING AND COMPUTER AIDED MODELLING COURSE OBJECTIVES: The students will be able to 1. Identify the various commands in sketching. 2. Analyze the difference between 2D & 3D modeling. 3. Draw different models using different software’s. 4. Summarize sketching, modeling &drafting features. 5. Develop assembly drawings using part drawings. COURSE OBJECTIVES: The students will be able to 1. Draw two- dimensional sketches in CAD environment. 2. Develop different views for any object in CAD environment. 3. Identify the difference between First angle & Third angle projections. 4. Decide the conventional representations of different materials. 5. Distinguish representation of common machine elements such as bolts, nuts, screws,

gears, ribs etc. 6. Recall the part drawings and create Assembly drawings. 7. Recommend the software to draw given machine element. 8. Summarize all the machine elements of Assembly drawing in Title Box.

LESSON PLAN

Name of the Faculty : Ch.Vinaykumar Reddy Academic Year: 2017 - 2018 Course Number : ME106 Course Name : TS& CAM Lab Program : B.Tech Branch : ME Year / Semester : II/I

S.No Topic Schedule

Dates (Batch-I)

Schedule Dates

(Batch-II)

1 Develop 3-D model using 2-D sketch by AUTOCAD extrude command 13-6-17 15-6-17

2 Develop 3-D model using 2-D sketch by AUTOCAD extrude cut command 20/6/17 22/6/17

3 Model a 2700 stepped shaft of given dimensions using Revolve command 27/6/17 29/6/17

4 By using Loft command, generate multi-section solid 4/7/17 6/7/17

5 By using Sweep command generate cut or extrude feature 11/7/17 13/7/17

6 By using Shell command generate different shell surfaces 18/7/17 20/7/17

7 By using extrude command generate a model using Pro/E 25/7/17 27/7/17

8 By using extrude-cut command generate a model using Pro/E 1/8/17 3/8/17

LAB INTERNAL EXAM-I 8/8/17 10/8/17


9 Model a nut and bolt for a given diameter of stud 25/8/17 17/8/17

11 Model a gear for a given diameter 29/8/17 27/8/17

12 Model different keys. 5/9/17 7/9/17

13 Knuckle joint Assembley 12/9/17 14/9/17

14 Screw jack Assembley 19/9/17 21/9/17

LAB INTERNAL EXAM-II 26/9/17 28/9/17

Time Table:

Monday : Thursday : 10.20-1.00

Tuesday : 1.40-4.00 Friday :

Wednesday : Saturday :

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