LECTURE PLAN - skiet.org36 Bending stresses in beam subjected to unsymmetrical 13th 37 Bending stresses in beam subjected to unsymmetrical bending 38 Bending stresses in beam subjected

LECTURE PLAN

Name : Er. Rajender

Discipline : Civil Engineering Semester : 4th

Subject : DSS-I Subject code: -CE:204 N Lesson Plan Duration : 15 weeks (from January, to April, 2018)

Week Theory Practical

Lecture

day

Topic (including assignment/ test) Practical day Topic

UNIT-1 1

st 1 Introduction- types of steel structures, advantages

& disadvantages of steel structures.

1st

2 Properties of structural steel

3 Indian Standard rolled steel sections and

specifications 2

nd 4 Types of loads- Permissible stresses in steel 2

nd

5 Connections--- Importance, types of connections

6 Riveted connections – types, permissible stresses,

riveted joints, failure of riveted joints

3rd

7 Design of rivet joints with example 3rd

8 Bolted connections

9 Bolted connections

4th

10 Types of welded joints 4th

11 Design of welded joint subjected to axial loads

12 Example

5th

13 Welded joints subjected to eccentric loads 5th

14 example

15 Simple, semi-rigid and rigid connections

6th

16 Introduction, types of tension members, net

sectional areas

6TH

17 Design of tension members

18 Lug angles and splices

UNIT-II 7

TH 19 Introduction, effective length and slenderness ratio 7

th

20 Various types of sections used for columns, built up

columns, necessity 21 Design of built up columns

8th

22 Laced and battened columns including the design of

lacing and battens

8th

23 Design of eccentrically loaded compression

members 24 Introduction, types of column bases

9th

25 Design of slab base footing 9th

26 Design of gusseted base footing

27 Design of gusseted base subjected to eccentrically

loading

10th

28 Design of grillage foundations 10th

29 ASSIGNMENT AND REVIEW

30 1ST

SESSIONAL TEST

UNIT-III 11

th 31 Introduction, types of beam sections 11

th

32 general design criteria for beams 33 Design of laterally supported beams

12th

34 Design of unsupported beams 12th

35 Design of built up beams 36 Web buckling, web crippling and diagonal buckling

UNIT-1V

13th

37 Introduction of Gantry girder 13th

38 Various loads and specifications of Gantry girder

39 Design procedure

14th

40 Design example on Gantry girder 14th

41 Introduction, elements of plate girder

42 Design steps of a plate girder

15th

43 Necessity of stiffeners in plate girder and types of

stiffeners

15th

44 web and flange splices (brief introduction),

Curtailment of flange plates 45 2ndSessional Test

LECTURE PLAN

Subject : Fluid Mechanics Subject code: -CE: 206 N

Lesson Plan Duration : 15 weeks (from January, to April, 2018) Practical code:-CE-212 N

Name : Ms Mandeep Saini Discipline : Civil Engineering

Semester : 4th


Lecture

day

Topic (including assignment/ test) Practical

day

Topic

UNIT-1 1

st 1 Navier Stokes’s equation 1

st To determine the coefficient

of drag by Stroke’s law for

spherical bodies.

2 Laminar flow between parallel plates

3 Laminar through pipe –Couette flow

2nd

4 Laminar through pipe –Hagen poiseuille law

5 Laminar flow around a sphere – stoke law

6 Type of flow Reynold’s experiment

3rd

7 Shear stress on turbulent flow 2nd

To study the phenomenon of

cavitations in pipe flow 8 Boundary layer in pipes

9 Velocity distribution of turbulent flow in smooth and

rough pipes

4th 10 Resistance to flow of fluid in smooth and rough pipes Stanton and moody’s diagram

3rd To determine the critical Reynold's number for flow through commercial pipes

11 Darcy’s weisbach equation ,Energy losses in pipes 12 Loss due to sudden expansion, hydraulic gradient and

total energy lines

UNIT-II 5

th 13 Types of drag, drag on a sphere 4th To determine the coefficient

of discharge for flow over a broad crested weir

14 Development of lift on immersed bodies like circular

cylinder and airfoil.

15 Type of flow in open channels

6th

16 Geometric parameters of channel section, uniform

flow

5th

To study the characteristics of a hydraulic jump on a

horizontal floor and sloping glacis including friction

blocks.

17 Specific energy and critical depth 18 Metering flumes, hydraulic jump in rectangular

channel, 7

th 19 Surges in open channels, positive and negative

surges

20 Gradually varied flow 21 Equation and its integration, surface profiles.

8th 22

Momentum in open channel

6th

To study the scouring phenomenon around a bridge

pier model. 23 flat plate, cylinder and airfoil 24 Cylinder and airfoil.

UNIT-III

9th

25

Ist Sessional Test

7th

To study the scouring phenomenon for flow past a

spur. 26 Basic concept of thermodynamics continuity

27 Momentum and energy equation

10th

28 Propagation of elastic waves due to compression of fluid

8th To determine the characteristics of a centrifugal

pump. 29 Mach number and its significance

30 Subsonic and supersonic flow

11th

31 Propagation of elastic wave due to disturbance in fluid

32 Mach cone ,stagnation pressure

33 Momentum continuity, its significance

UNIT-1V

12th

34 Reciprocating pumps their types 9th

To study the momentum characteristics of a given jet. 35 Work done single acting pump

36 Work done double acting pump

13th

37 Centrifugal pump

38 Component and parts and working

39 Head of a pump statics , Manometric head

14th

40 Moving flat vanes, Fluid jet on stationary 10th

To determine head loss due to various pipe fittings 41 Component and working of pelton wheel

42 Francis turbine, Setting of turbine

15th

43 Turbines ,working, Classification of turbine

44 Head and specific speed, Cavitations

45 2nd

Sessional Test

Lesson Plan

Name : Mr. Neelkanth

Discipline : Civil engg.

Semester: 4th

Subject: Soil Mechanics

Lesson Plan Duration : 15 week (from Jan., 2018 to April, 2018)

Work Load (Lecture per week) : Lecture-03, Practicals : 03

Week Theory

Lecture Day Topic

1

1 Soil formation and composition

2 Introduction, soil and rock, soil mechanics and foundation engineering, origin of soils, weathering,soil formation

3 Major soil deposits,Particle size ,shape,forces, soil structure, Principle clay minerals

2

4 Basic soil properties, introduction, three phase system,weight volume relationship, soil grain properties.

5 Grain size,sieve size,sedimentation analysis,consistency of soil,activity of clays,relative density of sands

6 Classification of soil, Plasticity chart

3

7 Permeability of soil,Darcy law,discharge and seepage velocity,lab. Determination,Field determination.

8 Numericals on above terms

9 Test and Discussion of Unit 1

4

10 Effective stress concepts: Principle of effective stress, effective stress under hydrostatic conditions, Capillary rise in soil

11 Hydrodynamic condition,Quick conditions,Two dimensional flow,Laplace equation,Flownet,Piping.

12 Compaction: Introduction, Role of moisture & compactive effect in compaction

5

13 Lb. determination of O.M.C. , Moisture density relationship, Compaction in field

14 Compaction of cohesionless soil

15 Moderately cohesive soils and clays, Field control of compaction.

6


17 Protective filters

18 Numericals on effective stresses

7

19 Numeral practice on soil water relationship

20 Numeral practice on compaction

21 Numeral practice on two dimensional flow

8

22 Assignment

23 Assignment discussion


9

25 Vertical stress below applied loads: Introduction , Boussinesq's eqn.,Vertical stress distribution

26 Numericals ,Newmark's influence chart

27 Westergaard's analysis, contact pressure

10

28 Compressibility and consolidation: Introduction, components of total settlement, consolidation process

29 1-D consolidation test, Void ratio-pressure relationships for sand & clays, NC & OC.

30 Cassagrande graphical method, Terzaghi theory, determination of coff. Of consolidation

11

31 Construction period settlement

32 Consolidation settlement

33 Secondary settlement

12

34 Numerical practice


36 Shear strength,Intro, Mohr stress circle, Mohr coulomb failure criterion, relationship b/w princi. Stresses

13

37 Direct shear test, UCS strength, triaxial compression test, Drainage condition and strength parameters

38 Vane shear test, shear characteristics of sands, NC CLAYS,OC CLAYS & partially saturated soils.

39 Sensitivity & thixotropy

14

40 Earth prssure: Intro., E.P. at rest, Rankine's active and passive earth ptress., Rankine E.P. theory.

41 canal outlet

42 Coulomb's E.P. theory, Cilman's graphical construction, Rebhann's construction.

15



45 Revision

Subject : Structure Analysis -II

Lesson Plan Duration : 15 weeks (from January, to April, 2018) Subject code: - CE-202N

LECTURE PLAN

Name : Ms. Sunita Discipline : Civil Engineering

Semester : 4th


Lecture

day


day

Topic

UNIT-1 1

st 1 Introduction

2 Static and Kinematic Indeterminacies 3 Castigliano's theorems

2nd

4 Castigliano's theorems

5 Strain energy method

6 Analysis of frames with one

3rd

7 Analysis of frames with one 8 Analysis of frames with two

9 Analysis of frames with two

4th 10 Redundant members using Castigliano's 2nd theorem. 11 Redundant members using Castigliano's 2nd theorem. 12 Redundant members using Castigliano's 2nd theorem.

UNIT-II 5

th 13 Analysis of continuous beams

14 Analysis of continuous beams

15 Analysis of continuous beams 6

th 16 Analysis of portal frames

17 Analysis of portal frames 18 Portal frames

7th

19 Portal frames 20 Portal frames

UNIT-III

21 Elastic centre 8th 22 Properties of analogous column

23 Applications to beam & frames 24 Parabolic and circular Arches,

9th

25 Ist Sessional Test

26 Bending Moment Diagram for various loadings,

27 Bending Moment Diagram for various loadings,

10th

28 Temperature effects, 29 Rib shortening 30 Axial thrust

11th

31 Radial Shear force diagrams



UNIT-1V

12th

34 Introduction

35 Centroidal principal axes of sections

36 Bending stresses in beam subjected to unsymmetrical

13th

37 Bending stresses in beam subjected to unsymmetrical bending

38 Bending stresses in beam subjected to unsymmetrical bending

39 shear centre, shear centre for channel

14th

40 shear centre, shear centre for channel

41 Angles and Z sections. 42 Introduction, uniformly loaded cables,

15th

43 Temperature stresses, three hinged stiffening Girder

44 Two hinged stiffening Girder

45 2nd

Sessional Test

Lesson Plan

Name : Mr. Sourabh Discipline: Civil engg.

Semester : 6th

Subject: Disaster Management



Week

Theory

Lecture

Day

Topic

1

1 Introduction to Disaster management

2 define and describe disaster,hazard,emergency,risk and disaster management

3 Types of hazard

2

4 disaster management cycle

5 Different stages of D.M.C.

6 Disaster mitigation and preparedness

3

7 Consequences and mittigation measures for various for earthquake, tsunami, cyclone,flood,

8 landslide drought

9 Man made hazards

4


11 Hazard and risk assessment : Assessment of capacity

12 Vulnerability

5

13 Risk mapping

14 stages in disaster and recovery

15 Associated problems

6

16 Emergency Management systems

17 Essential public health services, response

18 Recovery operations

7

19 reconstruction

20 Rehabilation

21 Risk mapping

8

22 assessment parameters

23 case study

24 case study of above terms

9


26 Capacity buildings

27 disaster management new skills of government

10

28 development of professional and elected representative for effective disaster

29 Role of media in effective disaster management

30 overview on effective disaster

11 31 Role of agencies like NDMA,SDMA and other international agencies

32 role of insurance sector. DM ACTS and NDMA guidelines

33 Application of geoformatics : use of remote sensing systems and GIS

12

34 Early warning system

35 Role of knowledge based expert systems in hazard scenario.


13

37 Integration of public policy

38 Planning and designing of infrastructure for disaster management

39 Community based approach in D.M.

14

40 Methods for effective dissemination of information

41 Ecological and sustainable development

42 Case studies

15

43 lessons and experiences

44 Imp. Disaster with reference to C.E.


LECTURE PLAN

Subject : Design of steel structure-II Subject code: -CE: 302 N

Lesson Plan Duration : 15 weeks (from January, to April, 2018)

Name : Rajender Discipline : Civil Engineering

Semester : 6th


Lecture

day


day

Topic

UNIT-1 1

st 1 Introduction

2 Scope of plastic analysis 3 Ultimate load carrying capacity of tension member

2nd

4 Ultimate load carrying capacity of tension member

5 Ultimate load carrying capacity of tension member

6 Ultimate load carrying capacity of compression member

3rd

7 Ultimate load carrying capacity of compression member 8 flexural members

9 Plastic collapse, analysis

4th 10 Plastic collapse, analysis 11 Plastic analysis applied to steel beams 12 Simple portal frames and design.

UNIT-II 5

th 13 Introduction

14 permissible stresses,

15 permissible stresses, 6

th 16 design of circular

17 design of circular 18 Rectangular and pressed steel tanks including staging.

7th

19 Rectangular and pressed steel tanks including staging. 20 Introduction, 21 various loads to be considered for the design of steel stacks,

8th 22 various loads to be considered for the design of steel stacks, 23 Design of steel stacks including foundation. 24 Design of steel stacks including foundation.

UNIT-III

9th


26 Transmission line towers

27 Microwave towers

10th

28 Design loads, classification, 29 Design procedure and specification 30 Introduction and brief description of various types of cold formed

sections

11th

31 Buckling, concepts of effective width

32 Effective sections, elements with stiffeners,

33 Design of compression and bending elements

UNIT-1V

12th

34 Loads, general arrangement

35 stability, design considerations

36 Design of purlins

13th

37 Design of purlins

38 Bracings and stepped columns.

39 Bracings and stepped columns.

14th

40 Design of roof trusses

41 Design of roof trusses 42 Design of roof trusses

15th

43 Industrial building frames

44 Industrial building frames

45 2nd

Sessional Test

LECTURE PLAN


Semester : 6th

Subject : Geotechnology-II Subject code: -CE: 308 N



Lecture

day


day

Topic

UNIT-1 1

st 1 Introduction, types of sections, earth dam foundations

2 causes of failure and criteria for safe design 3 control of seepage through the embankment,

2nd

4 control of seepage through the foundation

5 Drainage of foundations, criterion for filter design. Introduction to

rock fill dams

6 Causes of failure, factors of safety, stability analysis of slopes-total

stress analysis,

3rd

7 effective stress analysis, stability of infinite slopes types of failures of finite slopes,

8 analysis of finite slopes-mass procedure, method of slices, effect of

pore pressure,

9 Fellinius method to locate center of most critical slip circle, friction

circle method

4th 10 Tayler's stability number, slope stability of earth dam 11 steady seepage, during sudden draw down 12 During and at the end of construction.

UNIT-II 5

th 13 Depth of unsupported vertical cut, sheeting

14 bracing for deep excavation

15 associated with sheeting and bracing 6

th 16 modes of failure of braced cuts

17 pressure distribution behind sheeting 18 Introduction, types of cofferdams

7th

19 Introduction, types of cofferdams 20 design and lateral stability of braced cofferdams 21 design data for Cellular cofferdams,

8th 22 stability analysis of cellular cofferdams on soil 23 Rock, inter-lock stresses. 24 Rock, inter-lock stresses.

UNIT-III

9th


26 Purpose of sheet piles, cantilever sheet piles,

27 Depth of embedment in granular soils rigorous

10th

28 Simplified procedure, cantilever sheet pile, penetrating clay and limiting

29 Limiting height of wall 30 Methods of design

11th

31 free earth support method in cohesion less cohesive soils

32 fixed earth support method in cohesion less soils

33 Blum's equivalent beam method

UNIT-1V

12th

34 Soil improvement, shallow compaction, mechanical treatment

35 Lime stabilization, cement stabilization, lime fly ash stabilization

36 Dynamic compaction and consolidation,

13th

37 Bituminous stabilization, chemical stabilization,

38 pre-compression, lime pile and column

39 Stone column, grouting, reinforced earth.

14th

40 Terminology, characteristics elements of a vibratory systems,

41 Analysis of vibratory motions of a single degree freedom system- undamped free vibrations,

42 Undamed forced vibrations,

15th

43 criteria for satisfactory action of a machine foundation, degrees of

a freedom

44 Barken's soil spring constant, Barken's method of a determining natural frequency of a block foundation subjected to vertical oscillations.

45 2nd

Sessional Test

Lesson Plan

Name : Amandeep Bura Discipline: CIVIL

Semester : 6th

Subject: Irrigation engg.-1



Week

Theory

Lecture

Day

Topic

1

1 Irrigation-Necessity, advantages, disadvantages

2 need and development of irrigation in india

3 Crop season ,pattern. Impact on human and environment

2

4 soil water relationship,root zone,infiltration,consumptive use,field capacity,wilting point.

5 kor depth kor period. Duty of water.Relation b/w delta duty and base period. Consumptive use

6 All flooding methods

3

7 sprinkler irrigation and its systems. Design and maintainance of S.S.

8 Drip irrigation and its design


4

10 Cannal irrigation systems

11 Allignment of channels

12 losses in irrigation channels

5

13 design discharge and silt theories

14 design of alluvial channels

15 lacey's theory

6

16 kennedy's theory

17 comparison b/w above two

18 desins of both theories

7

19 Numerical practices

20 garret's diagram

21 lacey's diagram

8

22 numerical practices on garret's

23 elements in canal system


9

25 Water logging;effects,causes measures of prevention

26 linning of channels

27 recovery from deadlock

10

28 Type of linning

29 Design of lined channels

30 Land drainage and open drain

11 31 Advantages of tile drain,depth and numericals on it

32 Closed drains

33 land reclamation , Methods

12

34 Outlets for tiles drain


36 River training

13

37 methods of R.T.

38 Guidebanks and numerical

39 spurs, cutoff

14

40 numericals

41 canal outlet

42 Numericals on APM

15

43 sensitivity and setting


45 Discussion about Assignments

LECTURE PLAN

Subject : Transportation Engineering.-I Practical code: - CE-314 N

Lesson Plan Duration : 15 weeks (from January, to April, 2018) Subject code: - CE-310 N

Name : Amandeep Bura Discipline : Civil Engineering

Semester : 6th


Lecture

day


day

Topic

UNIT-1 1

st 1 Transportation and its importance. Different modes of

transportation.

Ist Aggregate Impact Test.

2 Brief review of history of road development in India and abroad

3 Road patterns. Classification of roads, Objectives of

highway

2nd

4 Saturation system of planning. 2nd

Los-Angeles Abrasion

Test on Aggregates 5 Tresagne, Telford and Macadam constructions

6 Planning surveys.

3rd

7 Main features of 20 years road development plans in India 3rd

Dorry's Abrasion Test

on Aggregates 8 Requirements of an idea highway alignment

9 Factors affecting alignment

4th 10 Surveys for highway alignment 4th

Deval Attrition Test on Aggregates.

11 Macadam constructions and roman 12 Macadam constructions and roman

UNIT-II 5

th 13 Cross section elements: friction, carriageway, 5

th Crushing Strength Test

on Aggregate 14 formation width, land width, camber, IRC,recommended

values

15 Types of terrain Design speed. 6

th 16 Sight distance, stopping sight 6

th Penetration Test on

Bitumen 17 distance, overtaking sight distance, overtaking zones, 18 intermediate sight distance, sight distance at intersections,

7th

19 Head light sight distance, set back distance. Critical locations for sight distance

20 Effects of centrifugal force. Design of superelevation. 21 Providing superelevation in the field. Radius of circular

curves. 8th 22

Extra-widening. Type and length of transition curves.

7th

Ductility Test on Bitumen

23 Gradient, types, values. Summit curves and valley curves 24 Their design criterion. Grade compensation on curves

UNIT-III

9th

25 First Sessional Test

26 Road user and vehicular characteristics. Traffic studies such

as volume, speed and O & D study 27 Parking and accident studies. Fundamental diagram of

traffic flow.

10th

28 Level of service. PCU. Capacity for non-urban roads. Causes and preventive measures for road accident

8th

Viscosity Test on Bituminous Material

29 Traffic control devices: signs, signals, markings and islands. 30 Types of signs. Types of signal

11th

31 Design of an isolated fixed time signal by IRC method.

32 Intersections at grade and grade separated intersections

33 Design of a rotary. Types of grade separated intersections.

UNIT-1V

12th

34 Sub grade soil evaluation: CBR test, 9th

Softening Point Test on Bitumen. 35 plate bearing test

36 Desirable properties of aggregates.

13th

37 Various tests, testing procedures

38 IRC/IS specification for suitability of aggregates

39 Proportioning of aggregates for road construction

14th

40 Trial and error and Routhfuch method 10th

Flash and Fire Point Test on Bitumen 41 Types of bituminous materials: bitumen, tar, cutback and

emulsions. 42 Various tests, testing procedures and IRS/IS specifications

for suitability of bituminous materials in road construction

15th

43 Bituminous mix, desirable properties. Marshall' method of

mix design.

44 Basic concept of use of polymers and rubber modified bitumen in bituminous mixes.

45 2nd

Sessional Test

LECTURE PLAN

Name : Ms Sunita


Subject : WST Subject code: -CE:312 N Lesson Plan Duration : 15 weeks (from January, to April, 2018)


Lecture

day


UNIT-1 1

st 1 Importance and necessity of water supply scheme 1

st

2 Water demands and its variations, Estimation of total quantity of water requirement

3 Population forecasting

2nd

4 Example on Population forecasting 2nd

5 Quality and quantity of surface water sources

6 Quality and quantity of ground water sources continued

3rd

7 Selection of a source of water supply 3rd 8 Types of intakes

9 Continued Types of intakes

UNIT-11 4th 4

th 10 Impurities in water and their sanitary significance

11 Physical Characteristics and analysis of water

12 Chemical Characteristics and analysis of water

5th

13 Chemical Characteristics and analysis of water continued 5th

14 Bacteriological Characteristics and analysis of water

15 Water quality standards as per IS: 10500 - 1992

6th

16 Water borne diseases 6th

17 1st Sessional Test 18 1st Sessional Test

UNIT-11I 7

th 19 Objectives, treatment processes and their sequence in

conventional treatment plant

7th

20 Screening, types of screens, purpose and design

21 Plain sedimentation, purpose, types of sedimentation tank

8th

22 Principle of sedimentation 8th

23 Design of sedimentation tanks 24 Sedimentation with coagulation & principle, process

involves

9th

25 Types of coagulants and requirements of a good coagulant 9th

26 Mixing basins

27 Flocculation units.

10th

28 Filtration – mechanism involved, types of filters 10th

29 Principleof slow sand filter, their construction details and

design criteria.

30 Design example

11th

31 Rapid sand filter, their construction details and design

criteria.

11th

32 Design example

33 Comparison and merits & demerit of slow & rapid sand filter

12th

34 Disinfection principles, types of disinfectant 12th

35 Requirement of good disinfectants 36 Aeration, aim and types of aeration units

UNIT-1V 13

th 37 Distribution systems and its type 13

th

38 Gravity system, Pumping System, Dual system

39 Merits & demerits of gravity, pumping & dual system

14th

40 Layout of Distribution System and its type 14th

41 Dead End System, Grid Iron System and their merits and

demerits.

42 Ring System, Radial System and their merits and demerits

15th

43 Distribution Reservoirs and its functions 15th

44 Determination of storage capacity of distribution reservoir

45 2nd

Sessional Test

LECTURE PLAN

Subject : Bridge Engineering Subject code: -CE-402 E


Name : Amandeep Bura Discipline : Civil Engineering

Semester : 8th


Lecture

day


day

Topic

UNIT-1 1

st 1 Definition

2 Component of bridge, Classification of bride

3 Selection of site, economical span

2nd

4 Aesthetics consideration

5 Investigation and essential design data

6 General IRC bridge code

3rd

7 Width of carriage way 8 Clearance, various load to be consider for the design

of road

9 Clearance, various load to be consider for the design

of railway bridge

4th 10 Detailed 11 Explanation of IRC standard live loads 12 Explanation of IRC standard live loads

UNIT-II 5

th 13 Various types of R.C.C bridge

14 Design of R.C.C culvert


6th




7th

19 Design of R.C.C T-beam bridge 20 Design of R.C.C T-beam bridge

21 Design of R.C.C T-beam bridge

8th 22 Design of R.C.C T-beam bridge 23 Design of R.C.C T-beam bridge 24 Design of R.C.C T-beam bridge

UNIT-III

9th

25 Fist Sessional Test

26 Various types of steel bridges

27 Various types of steel bridges

10th

28 Design of truss 29 Design of truss 30 Design of truss

11th

31 Plate girder bridge



UNIT-1V

12th

34 Piers, abutments,

35 Piers, abutments,

36 Wing-wall and approaches.

13th

37 Bearings, joints,

38 Bearings, joints,

39 Articulation and other details.

14th

40 Articulation and other details.

41 Various types, necessary investigations 42 Design criteria of well foundation.

15th

43 Design criteria of well foundation.

44 Design criteria of well foundation.

45 2nd

Sessional Test

LECTURE PLAN

Name : Mr Neelkanth


Subject : ESTIMATION & ACCOUNTS Subject code: -CE:408E Lesson Plan Duration : 15 weeks (from January, to April, 2018)


Lecture

day


UNIT-1

1st

1 Introduction, Principles of estimate, Units 1st

2 Items of work of a building

3 Items of work of a building

2nd

4 Different types of estimates 2nd

5 Types of approximate estimate

6 Types of detail estimate

3rd

7 Methods of estimation 3rd

8 Estimation of materials in single room building with

example with long wall & short wall method.

9 Estimation of materials in two rooms building with different

section of walls with long wall & short wall method with

example.

4th

10 Estimation of materials in single room building with center

line method example

4th

11 Estimation of materials in two rooms building with different

section of walls with center line method example.

12 Estimate of road work

5th

13 Estimate of road work 5th

14 Example

15 Estimate of canal

6th

16 Estimate of canal 6th

17 Assignment 18 Class Test

UNIT-11

7th

19 Introduction,definitionand necessity of specifications, types

of specifications.

7th

20 General specifications for bricks, cement, sand

21 General specifications for Sand and Gravel

8th

22 General specifications for water, lime & reinforcement 8th

23 Detailed specifications for Earth work & cement concrete.

24 Detailed specifications for brick work.

9th

25 Detailed specifications for flooring & DPC. 9th

26 Detailed specifications for RCC work

27 Detailed specifications for cement plastering and cement

pointing

10th

29 Detailed specifications for white washing, colour washing,

distempering and painting.

30 Assignment and removal of students of difficulties

31 Class Test

UNIT-III

11th

32 Purpose, importance & requirements of rate analysis

33 Procedure of rate analysis for item of Earth work

34 Procedure of rate analysis for item of concrete work

12th

Rate analysis of RCC works

35 Rate analysis of Brick works

36 Rate analysis of Plastering, painting, finishing (white

washing & distempering)

UNIT-1V

13th

37 Introduction, function of Public Works Department

38 Administrative Sanction, Technical Sanction & contract

guidelines

39 Types of contracts, their advantages & disadvantages.

14th

40 Tender, classification and acceptance of tender.

41 Earnest money, security money, retention money,

42 Measurement book, Muster Roll

15th

43 Cash book, preparation, examination and payment of bills,

first & final bills

44 Assignment and removal of students difficulties

45 Class Test

Lesson Plan

Name : Ms Mandeep Saini Discipline: Civil engg.

Semester : 8th

Subject: EIA (CE-422E)



Week Theory

Lecture Day Topic

1

1 Introduction of EIA

2 Environment management

3 Recycling

2

4 Quality control

5 reuse and Environmental management

6 Management of aquatic environment

3

7 Aquatic environment and Drainage basin

8 Water pollution, human activities on W.P. And water quality control.


4

10 Air quality management

11 Air pollution

12 Effects of human activities on air quality

5

13 Effects of air pollution on environment

14 Preventive measures

15 Solid waste Management

6

16 Various methods of solid waste disposal

17 Solid waste contribution in Air pollution

18 Sustainable development

7

19 Natural resources

20 Case studies


8

22 Human activities on solid waste

23 Solid waste live schemes


9

25 Land pollution

26 Cause of L.P.

27 Effects on environment

10

28 Effects of human activities on Land

29 Land quality management

30 Forest Resources

11

31 Minings

32 Use and over-expolitation, Deforestation

33 land reclamation , Methods

12 34 Human activities on forest resources.


36 Quality control standards

13

37 Care studies

38 Quality standards for Water

39 Quality standards for air

14

40 Care studies

41 canal outlet

42 Case studies

15



45 Revision

LECTURE PLAN

Subject : Geosynthetics

Lesson Plan Duration : 15 weeks (from January, to April, 2018) Subject code :- CE-414 E


Semester : 8th


Lecture

day


day

Topic

UNIT-1 1

st 1 Historical Development,

2 The Nomenclature, Function, 3 Use around the World

2nd

4 Applications

5 Development in India.

6 Raw Materials – Their Durability and Ageing:

3rd

7 Raw Materials, Durability, 8 Degrading Agencies,

9 Polymers, Biological

4th 10 Resistance 11 Chemical Resistance, 12 Weathering Resistance

UNIT-II 5

th 13 Fibres

14 Yarn, Nonwoven Geotextiles

15 Woven Geotextiles 6

th 16 D.S.F. Fabrics

17 Factors influencing Testing 18 Sampling,

7th

19 Physical Properties 20 Mechanical Properties 21 under Uniaxial loading

8th 22 Creep Testing 23 woven Geotextiles 24 Woven Geotextiles

UNIT-III

9th


26 Wind Erosion

27 Rain Water Erosion

10th

28 Erosion Control Measures, 29 Erosion Control Measures, 30 Placement of Geogrid

11th

31 Experimental Studies.

32 Advantages, Mechanism,

33 Modes of Failure

UNIT-1V

12th

34 Dharoidam,

35 Hiran II Dam

36 Meda Creek Irrigation Schem

13th

37 Lining of Kakarpar Canal

38

39

14th

40

41 42

15th

43

44

45 2nd

Sessional Test

LECTURE PLAN

Name : Mr Rajender


Subject : IWWT Subject code: -CE:406 E Lesson Plan Duration : 15 weeks (from January, to April, 2018)


Lecture

day


UNIT-1 1

st 1 Introduction and importance of subject 1

st

2 Effects of industrial wastes on stream

3 Effects of industrial wastes on sewerage system

2nd

4 Effects of industrial wastes on waste water treatment plant 2nd

5 Effects of industrial wastes on waste water treatment plant

6 Effects of industrial wastes on environment

UNIT-11 3

rd 7 Minimizing the effects of industrial effluent on waste water

treatment plant

3rd

8 Minimizing the effects of industrial effluent on receiving

stream

9 Minimizing the effects of industrial effluent on

conservation of water

4th

10 Minimizing the effects of industrial effluent by changing

the process

4th

11 Reuse of waste water

12 Volume and strength reduction of industrial waste water

5th

13 Neutralization, equalization and proportioning of waste

water

5th

14 ------------------------- Do ---------------------------------------

15 Assignment of 1st

and 2nd

Unit

6th

16 Removal of students dificulties 6th

17 1st Sessional Test 18 1st Sessional Test

UNIT-11I 7

th 19 Population equivalent and its importance 7

th

20 Example on population equivalent

21 Industrial effluent standards for disposal into inland surface

water source

8th

22 Industrial effluent standards for disposal on land for

Irrigation

8th

23 Numerical on population equivalent 24 Assignment of 3

rd Unit

UNIT-1V 9

th 25 Study of the Textile industry from waste generation and

its quality quality

9th

26 Treatment including brief overview of manufacturing

process of Textile industry

27 Study of the Tannery industry from waste generation and

its quality

10th


process of Tannery industry

10th

29 Study of the Sugar Mill industry from waste generation

and its quality


process of Sugar Mill industry

11th

31 Study of the Distillery industry from waste generation,

and its quality

11th


process of Distillery industry

33 Study of the Dairy industry from waste generation,

quality

12th


process of Dairy industry

12th

35 Study of the Pulp and Paper industry from waste

generation and its quality


process of Pulp and Paper industry

13th

37 Study of the metal Plating industry from waste


13th


process of metal Plating industry

39 Study of the Oil Refinery industry from waste


14th


process of Oil Refinery industry

14th

41 Study of the Nitrogenous Fertilizer industry from

waste generation, quality and its treatment including brief

overview of manufacturing process

42 Study of the Thermal Power Plant from waste

generation, quality and its treatment including brief


15th

43 Study of the Radioactive waste industry from waste

generation, quality and its treatment including brief


15th

44 Assignment of 4th

Unit and rectification of students

problems

45 2nd

Sessional Test

LECTURE PLAN

Subject : Railway Engineering and Airport

Lesson Plan Duration : 15 weeks (from January, to April, 2018) Subject code :- CE-40

Name : Ms Sunita Discipline : Civil Engineering

Semester : 8th


Lecture

day


day

Topic

UNIT-1 1

st 1 Rail transportation and its importance in India.

2 Permanent way: requirements and component 3 Gauges in India and abroad, Selection of gauge, Coning of wheels.

2nd

4 Adzing of sleepers. Rails: functions, composition of rail steel,

5 Types of rail sections, requirements of an ideal rail section, length of

rails.

6 Defects in rails. Creep of rails, Long welded rails and continuously

welded rails.

3rd

7 Sleepers: functions, requirements of an ideal sleeper. Types of sleepers:

8 Wooden, cast Iron, steel and concrete sleepers, advantages,

disadvantages and suitability of each type.

9 Sleeper density. Fastenings for various types of sleepers: fish plates,

spikes, bolts,

4th 10 Bearing plates, keys, chairs, jaws, tie bars. 11 Elastic fastenings. Ballast: functions 12 Requirements, types of ballast and their suitability.

UNIT-II 5

th 13 Necessity. Turnout: various components, working principle. Switch:

components, types

14 Crossing: components and types. Design elements of a turnout, design

of a simple turnout.

15 Layout plan of track junctions: crossovers, diamond crossing, single 6

th 16 Double slips, throw switch, turn table, triangle.

17 Signals: objects, types and classification. Semaphore signal: components,

18 Working and principal 7

th 19 Requirements / principles of a good interlocking system

20 Brief introduction to devices used in interlocking 21 Methods of control of train movements

8th 22 automatic block system, centralized train control 23 Uses of centralized train control 24 automatic train control system

UNIT-III

9th


26 Gradients, grade compensation

27 Super elevation,

10th

28 Cant deficiency, negative super 29 Maximum permissible speed on curves 30 Maximum permissible speed on curves

11th

31 Tractive resistances,

32 Types

33 Hauling capacity of a locomotive.

UNIT-1V

12th

34 Station, function

35 Classification, junction and Non junction

36 Terminal station

13th

37 Functions, types.

38 Marshalling yard

39 Necessity

14th

40 Marshalling yard, Functions, types

41 Types, Maintenance of railway track 42 Types of maintenance

15th

43 Brief introduction to mechanized maintenance,

44 M.S.P and D.T.M

45 2nd

Sessional Test

Documents

LECTURE PLAN - skiet.org36 Bending stresses in beam subjected to unsymmetrical 13th 37 Bending stresses in beam subjected to unsymmetrical bending 38 Bending stresses in beam subjected