Saturday, 29 August 2015

What should a Mechanical Engineer must know!

Well being a mechanical engineer student i personally think that basic concept is the most important thing every Mechanical Engineer should know and to remember those concept you must wrote them down on a paper and stick it on your wall so you can keep checking and remembering those basic concepts allow me to elaborate in case of thermodynamic ( you must know about zero,first,second law of thermodynamic and different formulas of enthalpy, understand of tables,of pressure ,temperature and curves etc) keep their short notes and use you gain knowledge on every holiday to solve real world problems must know ideal process cycles and its types and try to grap concepts of experiment and stick its notes close to your eyes
Fluid mechanics
For this you must know how to select a pump for certain requirement like you must know what is the head of pump pressure of pump and flow rate also you must know how to estimate pipe pressure and friction depending on is length ,diameter, and angle on which it is and most importantly pressure drop on different kinds of bends(must know about type of angle use in pipe and type of bends) how to find
center of (inertia,resultant force,resultant pressure) of shape on which fluid is carried this thing help in building (dams ,reservoirs for different fluids) and plus you should also know about CG (center of
gravitation) this help in building ships and floating stuff ,you must know about effect on pressure if you go down sea level inside fluid or go on high hills must know about how to use instrument and basic ideal gas laws and few application try to practice these concept every holiday
Mechanics of Material(MOM)
For MOM try to practice to remember bending moment, shear stress,torsional stresses, normal stresses,bending moment both (horizontally,vertically) moment of inertia of different shapes and objects must keep a chart on your wall to know difference of ductile and brittle cure mechanical properties (young modulus,yield strength of basic mostly use materials like aluminum,steel,brass,copper,iron etc) ,mohr circle etc and create a structure like cycle or other thing
using this concept or try to help those student who are making structure in there final year project
Design OF Machine Element(DOM)
keep remember basic things like different between rivet,screw,bolt,stud, and most most most important where to use them in come places you only use rivet you must know reason keep there  notes on your wall ,must type of keys and what material should we use same or different and flange design and other these thing try to solve there real problem by asking real engineer if you can or create your on and build product and test it or help final year student to build project
TOM (THEORY OF MACHINES)
Must know how to analysis mechanism, how to create mechanics mostly mechanism are made of 4 bar mechanism know ho to calculate velocity of component fore and all other stuff some mechanism are basic like train,umbrella,car roof mechanism and some are use in games like (wipe out try to look at these mechanism and think how it would have been made and create on paper find its velocity force ) and also you must keep notes of pulley and belts driver and follower,must know how to find best for your desired pulley ,types and uses and tables and about gears also type of gears uses how to
change direction method to find gear teeth

Heat and mass transfer (HMT)
Must know difference between conduction,convention,radiation and there formulas, and enthalpy,coefficient of convection,conduction etc which fluid ha what property and what is its use heat storage capacity and rate of heat transfer both in pip and solid wall must know how to design and
how to play with flow rate of pre -design pipe ,heat exchange and special cases of boiler,condenser effectiveness and efficiency trick to solve and other things like that keep remember must know which pump to use which design heat exchanger and effect of corrosion,environment speed etc keep their notes close to your eyes
IC Engine
Different types of engine parts of engine components which component has what effect what happen if leaking of on thing happen and real life cases of it how many parts to crankshaft mover what other components are connected with cam shaft and how camshaft control water pump,oil pump,radiator fan,vacuum section, carburetor parts, different condition of throttle and mixing ration change while,staring,cursing, cooing system different types and effect of environment case of different situations lubrication how and thrown which places oil move to lubricate and problem of flow of lubricate and its real life case try to communicate with your teacher math stuff must know all math formula and there use try to bring those formulas to real life pick one formula and work on it every holiday with real life situation

'A GOOD TEACHER IS A GIFT WHO CAN TELL YOU REAL LIFE PROBLEMS AND SITUATION'
Keep you interaction with your teacher who taught you and keep asking different question any doubt
and try to find those teachers who have experience in that field whose wisely because in your life only few courses you will be using it depend on you job type so focus on your dream work you want to do and for what you picked MECHANICAL ENGINEERING people die and new people come don't worry about job only do what you like its your life you life once.

Preparation for GATE 2016

Four things are vital for GATE preparation.
1. Theory
2. Problem practice
3.Revision
4. Test
Let me take each point one by one.
1. Theory:
First of all, go through the syllabus.
Page on iitk.ac.in
Either go through made easy notes which are easily available at any Xerox shop in Delhi,
OR
Make your own note from NPTEL.
NPTEL PHASE 2 - Courses
I will recommend you the second option (making notes from nptel) as it will build your concepts in
a much better way.
2. Problem Practice.
I will highly recommend you the following books.

GATE - Mechanical & PI Engineering 2016 : 28 Years
GATE Solved Papers with thorough Explanations (English) 1st Edition
GATE Practice Book 2016: Mechanical Engineering Book
IES 2015 Mechanical Engineering Topicwise Objective Solved Paper II
IES 2015 Mechanical Engg Topicwise Objective Solved Paper-I
Solving the first two is must. After solving these two if you still have enough time, go through the last two books also. Also, if possible, buy made easy notes and go through the problems in it. There are a few very good questions in it.
3. Revision.
This is one of the most important thing for GATE because irrespective of your preparation, if you don't have proper revision strategy, you are going to fail for sure. I have seen many students working really hard throughout the year and ending up with a very low rank because of lack of revision.
So, here is the key.
Make short notes. Go through the important formulas at least 10 times.
In short notes include all formulas and key points. This book is going to help you a lot in making short notes. A Handbook for Mechanical Engineering Book
4. Test.
Make your strategy in such a way that the last 45 days are dedicated only for giving tests. You can join any one or preferably both of these test series.
a) MADE EASY TEST SERIES
b) ACE ACADEMY TEST SERIES
Try to give each and every test of these two test series.
Giving test is very important because it is going to increase your problem solving speed and accuracy.
If you want to avoid making silly mistakes in the exam, give as many test as possible.
BEST OF LUCK FOR GATE'16

Friday, 28 August 2015

HR Round: tentative Questions:

1. Tell me something about yourself.
2. What do you know about Co?
3. Explain me any concept considering me as a layman.
4. Will you be able to work if posted in a place like Andaman?
5. What are your hobbies?
6. Tell me an interesting experience of your life.
7. Will you get married soon?
8. What will you do if you are told to work on something you don't know or like?
9. Tell something about yourself that is not in the resume.
10. What is your area of interest?
11. Why do you want to join this industry?
12. Would you work anywhere in the country?
13. What if we don’t select you today?
14. Tell me about your family, weakness and strength.
15. What is commitment? Do you have a girlfriend?
16. Do you consult your parents?
17. Will you stay away from your parents?
18. Will you do arranged or love marriage?
19. You are living in 21st century, you should take your own decisions. Then why consult parents?
20. Why should we hire you?
21. Tell me a few qualities that you have.
22. How much will you sell your project for?
23. What is your future plan?
24. How you being emotional help us?
25. Are you ready to relocate?
26. Will you be able to adjust yourself with people in Chennai?
27. Do you wish to go for higher studies?
28. Are you innovative enough?
29. What is your best achievement?
30. What has been your toughest decision till date?
31. Tell us about your journey.
32. Given a situation how would you resolve a conflict.
33. What would you do if your seniors are not noticing your work?
34. What has been your best experience till date?
35. Rate yourself on a scale of 1-5.
36. Are you aware about the Co eligibility, background check?
37. You have high percentage in SSC and HSC but low in engineering. Why?
38. What is your ambition in life?
39. What do you do in your free time?
40. Do you want to be in Co even after 3 years?
41. Why do you want to be in Co?
42. Why a job?
43. How happy are you with your parents decision?
44. What is the longest you have stayed away from your parents?
45. What are your expectations from TCS?
46. Where do you see yourself in the next 5 years?
47. Tell me about your teamwork.
48. What is your chance of getting selected?
49. Why should I select you compared to others?
50. Describe one instance when you have succeeded.
51. You are a project manager. How will you ensure that your project is completed on time?
52. What are the three keywords according to you for success?
53. Who is your role model?
54. In how many ways can you contribute to the society?
55. What is the meaning of your name? who do you have faith in?
56. Describe yourself in one line and in one word.
57. Do you think advantage of exemption from aptitude given to toppers is good or bad.
58. Which department would you like to go in?
59. If 20,000INR are given how will you manage it in a month? And how much will you save from that?
60. If not this Co where are you planning to go?
61. Tell me one instance when you worked as a team leader.
63. If you lead a project and the team members aren’t happy with you as the leader what will you
do?
64. How much time do you spend on the net? Tell me the most recent news that you have come
across.
65. What do you think of life?
66. Difference between creativity and innovation.
67. Difference between theorem and axiom.
68. Explain your interview experience in Marathi.
69. Where do you see yourself in the coming years?
70. What are your interests?
71. Tell me the story of any movie you saw recently.
72. Are you tired or nervous?
73. Are you sure you’ll take up the job and not go for further studies?
74. Why do you want to join an IT company? Since your percentage is so good? Will you work on
domains like database management, oracle, etc?
75. Difference between agile and waterfall.
76. How was your day?
77. How long did you wait? Was it worth the wait?
78. How do you manage to resolve conflicts within your siblings?
79. What books do you read?
80. How will you manage to live with females of other states?
81. If you are a team leader what 3 things do you think are most important ?
82. How do you make someone feel special?

Important Questions asked in Mechanical Engineering Interview!

I'm sharing this question list to fellow mechanical engineers that I made to prepare for an interview. It
contains two sections viz. technical questions followed by HR questions.
1. Technical questions:
Type of technical questions asked will be definition type and that too from basic. Your favorite subjects will be asked first and then they start questioning what they want you to answer. Some of the
questions are...

1. Why we do not use same technology to start both SI/CI engine?
2. Which one is more efficient? A four stroke engine or a two stroke and why?
3. 4 Stroke engine is more efficient primarily Because of the presence of valves which precisely control the flow of charge into the chamber and exit the exhaust gases with proper timing which is hard to achieve by ports in a 2 stroke engine.
4. Why there is no differential in a train. What happens when a train takes a turn?
5. A cantilever beam is loaded a point on its ends what will be the effect in shear force?
6. Why vehicle does not move when its gear is applied though parked in slope area?
7. What is shear force in fluid particle?
8. How gear ratio helps in power variation?
9. What is the angle of twist in drill?
10. What is the difference between impact force and sudden force?
11. How to calculate the turbine efficiency?
12. Why centrifugal pump casing is called involutes casing?
13. What will happen if reciprocating compressor run in exactly opposite direction?
14. What is the effect of clearance volume in performance of air- compressor?
15. What is the advantages and disadvantages of critical speed of turbine?
16. What will happen if oil is mixed with boiler feed water?
17. What is difference between fan and blowers?
18. What are the protections required to protect turbine?
19. what is critical temperature?
20. Air is a bad conductor of heat. Why it becomes hot in summer?
21. How many stages in compressor in there in gas turbine?
22. Which is more efficient? A rear engine Volvo Bus or a Front engine Volvo Bus? (Engine Capacity is same for both) why?
23. What is difference between stress and pressure?
24. What is Boiler HP?
25. What is Auto Dosing?
26. What happens when too much oil is injected in the working cylinder?
27. How many manholes should be there on boiler? Why?
28. What is used to check the amount & quality of fuel in two stroke IC engine?
29. Work done in throttling process is given by which formula?
30. Function of the strainer in IC engine?
31. What is the difference between the air pre-heater & air blower?
32. Why the compression ratio of the diesel engine should be high?
33. A vertical plate and a horizontal plate are suspended in an open room. Both are heated to the
same temperature. Which one will cool first? Why?
34. What is the color of flame if the boiler is running?
35. Which is the best lubricant-air, oil or water?
36. Tell the octane number in Indian petrol?
37. Difference between enthalpy & entropy?
38. What is the difference between safety valve and relief valve?
39. Explain cooling and its types?
40. What is the working principal of air compressor?
41. What is cryogenics and what are its fundamentals?
42. What is the difference between a shaper machine and a planner machine?
43. Why stress relieving of stainless steel is not roffered?
44. What are the advantages of PID controllers compared with those of a PLC?
45. Which two continents are mirror images of each other?
46. Where half nut is used?
47. What is the need for drafting?
48. Turbo charger driven by.............? and what its speed
49. Why...? Turbo charger used in DG....?
50. The stage below saturation is called?
51. Why is a condenser used in a Rankin cycle?
52. What is servo motor?
53. Can we use light duty vehicle axle into the heavy duty machinery axle? If no then why?
54. Stress strain diagram for fluid?
55. Where manning formula used?
56. What is level of documentations for a ISO 9001 certified company?
57. What is back plate in centrifugal pumps and its purpose?
58. Why tyres are manufactured in black colour?
59. Whether ductile material can fail in brittle manner? When?
60. On what property u can distinguish material as brittle or ductile?
61. Name fuels used in nuclear power plant?
62. On what thermodynamic cycle nuclear power plant works?
63. How can you increase the efficiency of power plant without changing in effort?
64. What is purpose of governor in Diesel engine?
65. Why petrol engines have more power than diesel engines of same capacity?
66. What is the difference between Torque and Power ( layman Idea)?
67. What will be the induced stress in the bar?
68. What is the Difference between Rated Speed and Economic Speed?
69. How to convert from HP to BHP or CC to Bhp please explain????????
70. How the material no. 2062 will mild steel of density 7.85? What are the other codes?
71. Why petrol engine gives more power than diesel engine even though diesel engine has high
compression ratio?
72. What is mean by Resistance welding?
73. Compare Brayton and Otto cycle.
74. Why we have to know the specific frequency of any equipment? does anybody know about specific frequency ?
75. What is pulverization?
76. What is the function of an isolator?
77. Why the back wheel of tractor is bigger than front wheel?
78. Flow will increase or decrease or remain same?
79. Why Mechanical seal used in Pumps?
80. The ratio of Emissive to absorption power of heat by a body is equal to heat emitted by a perfect
black body. Who said the statement
81. What is colour of flame if the of Halide Torch detects a refrigerant leakage?
82. How can we remove paint from (painted over) plastic or nylon objects with out damaging the
object?
83. How to calculate or arrive the capacity of a mechanical press?
84. The property of a metal that is determined by the indentation on a metal surface
85. The amount of thickness of the metal sheet that can be welded by ultrasonic welding is?
86. The amount of carbon present in Cast Iron?
87. Numeric control is used for?
88. The amount of moisture that is to be present in wood to be called dry wood is?
89. The pattern material used in Investment casting Process is?
90. What is the use of offset follower in cam? Why and where we have to use this type of follower?
91. What is the use of offset follower in cam? Why and where we have to use this type of follower?
92. State the difference between Forging & Fabrication?
93. What is flange rating?
94. What amount of heat energy loss in ESP?
95. What happen when diesel is injected in petrol engine?
96. What do you mean by property of system?
97. Why joule-Brayton cycle is not suitable for a reciprocating engine.
98. How does “turbulence” differ from swirl?
99. Is octane number beyond 100 is possible?
100. Explain the effect of fuel structure on knocking.
101. Discuss the advantages and disadvantages of LPG as a fuel in S.I. Engine?
102. What is the impact of using throttling device instead of expander in vapour compression cycle?
103. What is moisture choking? Which refrigerants are more prone to it?
104. What is Montreal protocol and why CFCs are being phased out?
105. Why reverse Joule Brayton is used in aircraft refrigeration system?
106. Explain how solar-energy can used in refrigeration system?
107. Is wet bulb temperature a thermodynamic property?
108. What is the utility of comfort chart?
109. How would you decide whether a reciprocating compressor or centrifugal compression is to be
used in a refrigerating system?
110. Why smoking is not allowed in air conditioned enclosure?
111. Why desert coolers become ineffective in raining season?
112. Why package units are being preferred over central air conditioning system?
113. What is MAPI.
114. What is capital budgetary?
115. What is group technology layout?
116. What is leveling & smoothing in production technology?
117. What is deference between method study & work measurement?
118. What you know about drilling?
119. How oil is produced? What is the size of well?
120. Pumps used in drilling procedure and why? Why not centrifugal pump? What if we want high
head and high discharge?
121. Difference between Pipeline and Piping ?
122. Use of CNG, LNG, LPG etc.
Additional questions subject wise:

Fluid Mechanics and Fluid Machinery
What is the difference between impulse & reaction turbine.
Explain unit speed, unit discharge unit power & specific speed.
Explain NPSH, in which parameter it depends on.
What is jet ratio?
What is Deriaz turbine?
Which turbine is good for tidal power plant?
What is Navier-stroke equation.
What are the significance of
Mach number
Weber number
Material Science
What is quazi-crystal?
What do you understand by a free cutting steel?
What elements are usually added to make a steel free cutting, & how they make the steel free cutting?
Explain various method of hardening of steel?
What do you understand by the term “Arrest point” in connecting with heat treatment of plain carbon steel?
What influence does grain size have on the mechanical properties of metals.
Describe the difference between brittle and ductile fracture.
What is the difference between natural & artificial aging?
Thermodynamics
What is availability function for a closed system?
If it is possible that entropy of a system can decrease during a given process?
What is dead state in thermodynamics?
What is exergy?
What happens to triple point line when projected to P-T plane?
What is compressibility factor and what is its value for Vander walls gases.
What are initial conditions for formation of shock waves?
What do you understand by choking in nozzle flows?
Is it possible that pressure and velocity decreases simultaneously/
Distinguish between “Available energy” & Availability?
What is pure substances.
What is critical point? What is the value of critical temperature, pressure & volume of water?
What is sublimation curve, fusion curve & vaporization curve?
What is Rayleigh Line & Fanno Line?
What is normal shocks & when its occurs?
What is High Grade Energy & Low Grade Energy?
Heat & Mass Transfer
What is Newton’s Law of cooling.
What is Recuperator & Regenerators?
Whether fin can actually reduce heat transfer? is it possible? When?
What is difference between Biot no. & Nusselt no?
Which one is greater, thermal boundary layer or hydrodynamic boundary layer?
What is film temperature in forced convection flow?
What is fully developed region and where it is applicable?
What is the critical radius of insulation, explain clearly in terms of thermal resistance and heat
transfer rate?
At what case do you recommend Fin?
What is the difference between free convection & forced convection in what parameter forced &
free convection depend.
Internal Combustion Engine What is the use of Carburetor in SI Engine, There is trend towards increases of injection system in
Automobiles, Explain.
Why Supercharging is not popular with SI Engines?
What is performance number.
Explain Knocking in SI Engine & Mention, the factor that tend to reduce Knocking?
Explain the difference between Knocking in SI Engine & CI Engine?
How does “Turbulence” differ from “Swirl”?
Name some Antiknock additive and explain the Mechanism by which they reduce the knock?
Power Plant engineering
What is slip ratio in thermal power plant?
In Pendant super heater whether parallel flow or counter flow heat exchange between steam and flue gases.
What happens to mass flow in case of supersaturated flow?
Why clearance are provided in reciprocating compressor?
Explain turbojet & Rocket Engine.
What’s the advantage of compounding of steam turbine?
What’s are boiler mounting & accessory.
Draw the sketch of pulse jet engine. What are its main advantage & disadvantage?
Explain working principal of scram jet engine,
what is advantage over the ramjet?
What are the advantage of nuclear power plants over thermal power plants.
What is fast breeder reactor?
What is circulation ratio and what is its range in power plant?
One 2-row Curtis turbine is equivalent to how many reaction turbines for same value of blade velocity and angle of nozzle?
What are thermal neutrons?
What is breeding ratio?
What is the application of jet and rocket technology? Which is used in missiles?
Strength of Materials
What do you mean by equal strength in a beam?
What is difference between pure shear and simple (normal) shear?
Is it possible that decrease in area gives a decrease in stress?
Whether shear stresses are always parallel to shear forces?
By which experiment, you find it toughness of material.
Distinguish between direct stress & bending stress.
What do you mean by Torsional rigidity & lateral rigidity?
Define “slenderness ratio”. How it is used in long and short column?
Machine Design
What are rolling contact bearing?
What are the anti friction bearings?
What is stress concentration factor?
What is the bolt of uniform strength?
What is the difference Static Load carrying
capacity & Dynamic Load carrying capacity?
Why we are not using the unit joule for torque instead of N-m.
What is Low cycle fatigue failure and High cycle fatigue failure? What are considerations of these while designing a machine?
What is mechanical advantage?
How trains take turns though there is no differential gear?
Do you know epicyclical gear box? What is the practical application of epicyclical gear box?
What is tooth profile? Which one is better?
Theory of Machines
What is Keneddy theorem?
Do we need a screw with efficiency less than 50%?
What is backlash?
What is damping ratio?
Define Resonance.
Define critical speed or whirling speed or
whipping speed.
What is machine? Giving example, Differentiate
between a machine & structure.
What is Mechanical advantage.

Refrigeration and Air-conditioning
What is utility of comfort chart?
hat is wet compression?
To maximize COP what should be the condition of vapour at suction to compression?
What is the range of NBP (normal boiling point) in case of most refrigerants?
Why COP of CO2 gas is less and still why it is used in transport refrigeration?
What are the most crucial parts in reciprocating compressors?
How compressors are selected based on type of refrigerant?
What is correlation between wet bulb
temperatures an adiabatic saturation temperature?
Why isothermal compressor is Desirable?
What is desirable property of ideal refrigerant?
Define effective temperature & what is the optimum design condition for comfort for summer A/C?
Production Engineering
Why arc is slowly extinguished in case of arc welding?
Which inert gas is commonly used for thin work piece and which inert gas for thick work piece?
What is friction welding?
What is difference between brazing & braze welding?
Why hole basis system is adopted in manufacturing?
What is 3- 2-1 principle?
Where diamond pin locator is used?
How presses are rated?
What is spring back?
What is difference between fillet and corner radius?
What are overhead costs?
Why depreciation is to be taken into account in industrial management?
Why breakeven point is important in any industry?
What is sine bar?
What is marginal cost and marginal revenue?
What is shear and where it is provided in case of punching and blanking?
What is angle of bite?
What is extrusion ratio?
What is gutter and where it is used?
Which process is used for making nuclear reactor fuel rods?
What is difference between Amorphous and crystalline solids?
What are the various method of inspection of
casting for internal & external defects?
Why are allowances provided for in the
production of patterns? What do they depend on?
What is the deference between soldering & brazing?
What is meant by solid-state welding explain.
What is cold welding?
Describe the principal behind resistance welding processes.
What function should a lubricant perform in manufacturing process?
Explain the difference between punching & blanking.
Explain the difference between discontinuous chips and segment chips.
Explain the different type of tool wear.
What is difference between oblique & orthogonal cutting.
What are the main difference between jig and fixture?
What is AOQ
What is LTPD
What is Producer risk
What is Consumer’s risk
What is JIT approaches?
What is group technology? What are its main advantages?
Define the term “production & productivity.
What is the significance of ISO 9000 series & 1400 series.
What is artificial intelligence?
Which welding process does not required any filler material?
What is tack weld?
Which process used for cutting thicker plates?
Where drooping characteristics of power source is required in arc welding?
2. HR questions:
1. Tell me about yourself?
2. What is your hometown famous for?
3. Tell about your achievements in life.
4. Your strengths and weakness
5. Are you a team player?
6. Tell me about your ability to work under pressure.
7. How would you know you will be successful on this job?
8. Describe your management style.
9. Global warming
10. Chief justice of India
11. Vice President of India
12. CEO of Apple, when did he die?
13. Gas scenario
14. RBI policy
15. Corporate Governance
16. Corporate Laws
17. Cast system is boon or bane ?
18. What’s the difference in the modus operandi of Amir Khan’s “Satyameva jayate” and Anna Hazares movement?
19. What will u do on your part to remove corruption? If you travel in a train without confirmed ticket will u bribe the TT for a seat?
20. What do u mean by optimistic. Is it always good to be optimistic or it helps sometimes to be pessimist?
21. What is difference between confidence and over confidence?
22. What is the difference between hard work and smart work?
23. What are your goals?
24. What motivates you to do a good job?
25. What makes you angry?
26. Give an example of your creativity
27. Describe ideal company, job, and location?
28. What are your hobbies?
29. Inspiration in your life and why?
30. What was the toughest decision you ever had to make?
31. Define success? and how do you measure up to your definition
32. About present job (if employed)
33. Why did you resign from your previous job?
34. Why have you been unemployed so long?
35. What was the toughest challenge you have ever faced?
36. What would you say to your boss if he is crazy about an idea, but you think it stinks?
37. Why should I hire you?
38. Explain how you would be an asset to this organisation.
39. If we give you a job will you leave IIT B or your organisation?
40. What changes would you make if you came on board?

Wednesday, 19 August 2015

GATE 2016 Mechanical Engineering Syllabus

Section 1: Engineering Mathematics
Linear Algebra: Matrix algebra, systems of linear equations, eigenvalues and eigenvectors.
Calculus: Functions of single variable, limit, continuity and differentiability, mean value theorems, indeterminate forms; evaluation of definite and improper integrals; double and triple integrals; partial derivatives, total derivative, Taylor series (in one and two variables), maxima and minima, Fourier series; gradient, divergence and curl, vector identities, directional derivatives, line, surface and volume integrals, applications of Gauss, Stokes and Green’s theorems.
Differential equations: First order equations (linear and nonlinear); higher order linear differential equations with constant coefficients; Euler-Cauchy equation; initial and boundary value problems; Laplace transforms; solutions of heat, wave and Laplace's equations.
Complex variables: Analytic functions; Cauchy-Riemann equations; Cauchy’s integral theorem and integral formula; Taylor and Laurent series.
Probability and Statistics: Definitions of probability, sampling theorems, conditional probability; mean, median, mode and standard deviation; random variables, binomial, Poisson and normal distributions.
Numerical Methods: Numerical solutions of linear and non-linear algebraic equations; integration by trapezoidal and Simpson’s rules; single and multi-step methods for differential equations.
Section 2: Applied Mechanics and Design
Engineering Mechanics: Free-body diagrams and equilibrium; trusses and frames; virtual work; kinematics and dynamics of particles and of rigid bodies in plane motion; impulse and momentum (linear and angular) and energy formulations, collisions.
Mechanics of Materials: Stress and strain, elastic constants, Poisson's ratio; Mohr’s circle for plane stress and plane strain; thin cylinders; shear force and bending moment diagrams; bending and shear stresses; deflection of beams; torsion of circular shafts; Euler’s theory of columns; energy methods; thermal stresses; strain gauges and rosettes; testing of materials with universal testing machine; testing of hardness and impact strength.
Theory of Machines: Displacement, velocity and acceleration analysis of plane mechanisms; dynamic analysis of linkages; cams; gears and gear trains; flywheels and governors; balancing of reciprocating and rotating masses; gyroscope.
Vibrations: Free and forced vibration of single degree of freedom systems, effect of damping; vibration isolation; resonance; critical speeds of shafts.
Machine Design: Design for static and dynamic loading; failure theories; fatigue strength and the S-N diagram; principles of the design of machine elements such as bolted, riveted and welded joints; shafts, gears, rolling and sliding contact bearings, brakes and clutches, springs.
Section 3: Fluid Mechanics and Thermal Sciences
Fluid Mechanics: Fluid properties; fluid statics, manometry, buoyancy, forces on submerged bodies, stability of floating bodies; control-volume analysis of mass, momentum and energy; fluid acceleration; differential equations of continuity and momentum; Bernoulli’s equation; dimensional analysis; viscous flow of incompressible fluids, boundary layer, elementary turbulent flow, flow through pipes, head losses in pipes, bends and fittings.
Heat-Transfer: Modes of heat transfer; one dimensional heat conduction, resistance concept and electrical analogy, heat transfer through fins; unsteady heat conduction, lumped parameter system, Heisler's charts; thermal boundary layer, dimensionless parameters in free and forced convective heat transfer, heat transfer correlations for flow over flat plates and through pipes, effect of turbulence; heat exchanger performance, LMTD and NTU methods; radiative heat transfer, Stefan-Boltzmann law, Wien's displacement law, black and grey surfaces, view factors, radiation network analysis.
Thermodynamics: Thermodynamic systems and processes; properties of pure substances, behaviour of ideal and real gases; zeroth and first laws of thermodynamics, calculation of work and heat in various processes; second law of thermodynamics; thermodynamic property charts and tables, availability and irreversibility; thermodynamic relations.
Applications: Power Engineering: Air and gas compressors; vapour and gas power cycles, concepts of regeneration and reheat. I.C. Engines: Air-standard Otto, Diesel and dual cycles. Refrigeration and air-conditioning: Vapour and gas refrigeration and heat pump cycles; properties of moist air, psychrometric chart, basic psychrometric processes. Turbomachinery: Impulse and reaction principles, velocity diagrams, Pelton-wheel, Francis and Kaplan turbines.
Section 4: Materials, Manufacturing and Industrial Engineering
Engineering Materials: Structure and properties of engineering materials, phase diagrams, heat treatment, stress-strain diagrams for engineering materials.
Casting, Forming and Joining Processes: Different types of castings, design of patterns, moulds and cores; solidification and cooling; riser and gating design. Plastic deformation and yield criteria; fundamentals of hot and cold working processes; load estimation for bulk (forging, rolling, extrusion, drawing) and sheet (shearing, deep drawing, bending) metal forming processes; principles of powder metallurgy. Principles of welding, brazing, soldering and adhesive bonding.
Machining and Machine Tool Operations: Mechanics of machining; basic machine tools; single and multi-point cutting tools, tool geometry and materials, tool life and wear; economics of machining; principles of non-traditional machining processes; principles of work holding, design of jigs and fixtures.
Metrology and Inspection: Limits, fits and tolerances; linear and angular measurements; comparators; gauge design; interferometry; form and finish measurement; alignment and testing methods; tolerance analysis in manufacturing and assembly.
Computer Integrated Manufacturing: Basic concepts of CAD/CAM and their integration tools.
Production Planning and Control: Forecasting models, aggregate production planning, scheduling, materials requirement planning.
Inventory Control: Deterministic models; safety stock inventory control systems.
Operations Research: Linear programming, simplex method, transportation, assignment, network flow models, simple queuing models, PERT and CPM.

What do Mechanical Engineers do?

Scientists dream about doing great things. Engineers do them.”

-James A. Michener
Engineers solve complex problems for society. Mechanical engineers create and build mechanical devices. They apply the fundamentals of science and math to create practical, useful solutions that the rest of us can use.
The diverse mechanical engineering field can be divided in a variety of ways in terms of job functions. Some of the most common functions relate to these areas of technology, but not all do. Among these fields are:
  • Product Design -- developing products ranging from biomedical devices to gasoline-powered engines. A mechanical engineer designs anything that uses mechanical motion.
  • Research and Development -- discovering new solutions to human needs or improving older methods.
  • Manufacturing -- developing the machines that process materials into products. Designing and building machines and systems of machines that improve operating efficiency is of prime importance.
  • Systems management -- overseeing operations of a large system, such as a power plant, as well as supervising the people who work there.
  • Energy -- planning how energy is generated, stored, and moved. Industries that produce and deliver electrical power, such as natural gas, oil and alternative energy, employ mechanical engineers to develop more fuel-efficient cars, motors, and appliances.
In most of these fields, the mechanical engineer is concerned with heat utilization or machine design--in other words, harnessing or creating energy. Heat utilization techniques are applied in boilers, air conditioners, and refrigeration units. Machine design is more focused on hardware, including automobile engines, computers, and washing machines.

Problems faced in your final year project and ways to avoid them

Your academic project would be a demanding, but an exciting learning experience. However, it is not without problems which, if not identified and addressed, could seriously effect the final result and ultimately reduce your marks. Here we mentioned some of these problems and how to avoid them
The “Overachiever” Problem:
A common problem is selecting a topic that is far too ambitious for the allotted time.   Remember that you have only a few weeks to finish the design, development and testing of your project. Be careful not to select a topic that is unrealistically large.  This can lead to frustration as well as errors caused by “cutting corners” and hurrying through the implementation.  Discuss with your supervisor the scale of what you are planning.  If he or she thinks it may be too large, consider implementing the project in stages, each complete in itself.  When stage I is working move on to stage II.  If you do not finish stage II, however, you still have a functioning system.
The “Do It Tomorrow” Problem:
The project weeks alloted for completion sounds like a long time, but it goes by quickly.  You need an implementation schedule that allocates reasonable amounts of work throughout the entire semester. Then you must stick to that schedule.  Don’t be tempted to postpone work on the project because your due date seems so far off.  All that happens is that during the final few weeks you rush madly to get something working, and project implemented in a rush rarely works correctly!
The “Sleeping Member” Problem:
In the ideal world, all team members have equal ability, equal interest in the problem, and work equally hard.  In the real world that may not happen.  You may have one (or more) team members who do not carry their share of the workload, not because of a lack of ability, but rather lack of interest or motivation.  This is a serious problem because, although part of your marks is based on each individual’s effort, another part is based on successfully finishing the project.  A non-contributing team member can slow down or prevent completion of the work.  If you have a teammate who is not doing his or her share of the work, talk to them and stress the importance of everyone doing their job.  If this does not solve the problem then talk to your supervisor.  Don’t let the failure of others prevent you from completing the work and receiving good marks.
The “Poop Out At The End” Problem:
You have worked hard for many weeks to complete the project. You have spent many late nights and chased down hundreds of bugs, but it is now working, so are you done?  Absolutely not!  The project evaluation is not based only on the programs you develop but also on your written reports and oral presentations.  Even though you may be “burned out” from implementation, remember there is still work to do. Don’t produce a poorly witten paper or give a poorly organized presentation.  That will negate much of your good work. Put in the time needed to prepare both a well written, high-quality final report and a well organized, polished presentation. A good job on these last steps will insure that you receive the marks that fairly represents the work you have done.


Tips for Perfect Final Year Project

For an effective project, it is advisable to carry out the following activities
  • Defining the objectives of the project.
  •  Acquiring background information about the problem and its possible solutions.
  • Establishing the criteria by which your solution(s) to the problem will be judged.
  • Determining by what process the work will be carried out.
  • Planning the detailed phases of the project.
  • Adopting one or more design methodologies.Analysing requirements.
  • Using (or constructing) tools.
  • Construction of one or more artefacts (hardware, software, document).
  • Evaluating your solution to the problem.Reporting on your work.


    Whatever the nature of the problem you set out to solve, the conclusion of your project should be whether you solved it successfully or not.

Quotes

The monogram of our national initials, which is the symbol for our monetary unit, the dollar, is almost as frequently conjoined to the figures of an engineer's calculations as are the symbols indicating feet, minutes, pounds, or gallons. … This statement, while true in regard to the work of all engineers, applies particularly to that of the mechanical engineer..
— Henry R(obinson) Towne
"We don't see the things the way they are, We see things the Way We are"- Talmund

"Opportunity is missed by most people because it is dressed in overall and looks like work"
- Thomas A Edison


GATE Books for Mechanical Engineering

GATE Books for Mechanical Engineering
S.NO.       SUBJECT                                                                         AUTHOR
1               ENGINEERING Thermodynamics                      P.K. Nag; Cen gel and Boles
2.              I.C. Engine                                                           R.P. Sharma M. L. Mathur, R. P. Sharma
3.             Gas Turbine and Propulsive Systems                    PR Khajuria & SP Dubey; V ganesan
4.             Fluid Mechanics                                                    D.S. Kumar; k.l.kumar; Cengel                                                                                                 & Cimbala, Frank m. white
5.             Compressible Flow                                                S.M. Yahya; John D. Anderson
6.             Heat and Mass Transfer                                         P. K Nag; JP Hollman; D.S. Kumar;                                                                                                          R.C. Sachdeva
7.             Refrigeration and Air Conditioning                       P. K Nag; CP Arora; Domkundwar
8.             Fluid Machinery                                                     D. S. Kumar; Jagdish Lal; RK Bansal
9.            Theory of Machines                                                S S Rattan , Thomas Bevan
10.          Mechanical Vibration                                              V.P Singh; G.K. Grover
11.          Machine Design                                                      Shigley , VB Bhandari
12.          Material Science                                                     WD Callister IP Singh
13.          Production Engg.                                                    P. N. Rao ( Vol I & II) ,Kalpkjian Schmid                                                                                                Amitabh Ghosh & AK Malik
14.         Industrial Engg.                                                       O. P. Khanna Buffa & Sarin
15.         Operations Research                                               A.M. Natarajan, P.Balasubramani
16.         Strength of Materials                                              Timoshenko gere, RAMAMRUTHAM,
                                                                                              B.C. Punamia

Bench Vice Assembly

Bench vise - a holding device attached to a workbench; has two jaws to hold workpiece firmly in place. vise. holding device - a device for holding something. jaw - holding device consisting of one or both of the opposing parts of a tool that close to hold an object.




Plumber Block Assembly

A pillow block, also known as a plummer block or bearing housing, is a pedestal used to provide support for a rotating shaft with the help of compatible bearings & various accessories. Housing material for a pillow block is typically made of cast iron or cast steel.

Selection

Pillow blocks are usually referred to the housings which have a bearing fitted into them and thus the user need not purchase the bearings separately. Pillow blocks are usually mounted in cleaner environments and generally are meant for lesser loads of general industry. These differ from "plummer blocks" which are bearing housings supplied without any bearings and are usually meant for higher load ratings and corrosive industrial environments. However the terms pillow block and plummer block are used interchangeably in certain parts of the world.
The fundamental application of both types is the same which is to mount bearings safely enabling their outer ring to be stationary while allowing rotation of the inner ring. The housing is bolted to a foundation through the holes in the base. Bearing housings are either split type or unsplit type. Split type housings are usually two piece housings where the cap and base can be detached, while certain series are one single piece housings. Various seals are provided to prevent dust and other contaminants from entering the housing. Thus the housing provides a clean environment for the expensive bearings to freely rotate, hence increasing their performance and duty cycle.
Bearing housings are usually made of grey cast iron. However various grades of metals can be used to manufacture the same.
ISO 113 specifies internationally accepted dimensions for plummer blocks.

Tuesday, 18 August 2015

Carburetor

A carburetor (American and Canadian spelling), carburator , carburettor, or carburetter ( Commonwealth spelling ) is a device that blends air and fuel for an internal combustion engine. It is sometimes colloquially shortened to carb in North America or carby in Australia. [citation needed]
Etymology
The word carburetor comes from the French carbure meaning " carbide". [1] Carburer means to combine with carbon. In fuel chemistry, the term has the more specific meaning of increasing the carbon (and therefore energy) content of a fluid by mixing it with a volatile hydrocarbon.
History and development
The carburetor was invented by an Italian, Luigi De  Cristoforis, in 1876. [citation needed] A carburetor was developed by Enrico Bernardi at the University of Padua in 1882, for his "Motrice Pia", the first petrol combustion engine (one cylinder, 121.6 cc) prototyped on 5 August 1882.[ citation needed ]
A carburetor was among the early [when? ] patents by Karl Benz as he developed internal combustion engines and their components. [2]
Early carburetors were the surface carburetor type, in which air is charged with fuel by being passed over the surface of gasoline. [3]
The world's first carburetor for the stationary engine was invented by the Hungarian engineers János Csonka and Donát Bánki in 1893.[4][5] Parallel to this, the Austrian automobile pioneer Siegfried Marcus invented the rotating brush carburetor .[citation needed]
Frederick William Lanchester of Birmingham, England, experimented with the wick carburetor in cars. In 1896, Frederick and his brother built the first gasoline-driven car in England: a single cylinder 5 hp (3.7 kW) internal combustion engine with chain drive. Unhappy with the performance and power, they re-built the engine the next year into a two-cylinder horizontally opposed version using his new wick carburetor design.
In 1885, Wilhelm Maybach and Gottlieb Daimler developed a float carburetor for their engine based on the atomizer nozzle.[6]
Carburetors were the usual method of fuel delivery for most US-made gasoline -fueled engines up until the late 1980s, when fuel injection became the preferred method. [7] (This change was dictated more by the requirements of catalytic converters than by any inherent inefficiency of carburation; a catalytic converter requires much more precise control over the fuel / air mixture, to closely control the amount of oxygen in the exhaust gases.) In the U.S. market, the last carbureted cars were:
1990 (General public) : Oldsmobile Custom Cruiser, Buick Estate Wagon, Cadillac Brougham, Honda Prelude (Base Model), Subaru Justy
1991 (Police) : Ford Crown Victoria Police Interceptor with the 5.8 L (351 cu in) engine.
1991 (SUV) : Jeep Grand Wagoneer with the AMC 360 engine.
1993 Mazda B2200 (Light Truck)
1994 (Light truck) : Isuzu[8]
In Australia, some cars continued to use carburetors well into the 1990s; these included the Honda Civic (1993), the Ford Laser (1994), the Mazda 323 and Mitsubishi Magna sedans (1996), the Daihatsu Charade (1997), and the Suzuki Swift (1999). Low-cost commercial vans and 4WDs in Australia continued with carburetors even into the 2000s, the last being the Mitsubishi Express van in 2003. Elsewhere, certain Lada cars used carburetors until 2006.
Many motorcycles still use carburetors for simplicity's sake, since a carburetor does not require an electrical system to function. Carburetors are also still found in small engines and in older or specialized automobiles , such as those designed for stock car racing , though NASCAR 's 2011 Sprint Cup season was the last one with carbureted engines; electronic fuel injection was used beginning with the 2012 race season in Cup. [9]
Principles
The carburetor works on Bernoulli's principle : the faster air moves, the lower its static pressure, and the higher its dynamic pressure. The throttle (accelerator) linkage does not directly control the flow of liquid fuel. Instead, it actuates carburetor mechanisms which meter the flow of air being pulled into the engine. The speed of this flow, and therefore its pressure, determines the amount of fuel drawn into the airstream.
When carburetors are used in aircraft with piston engines, special designs and features are needed to prevent fuel starvation during inverted flight. Later engines used an early form of fuel injection known as a pressure carburetor . Most production carbureted (as opposed to fuel-injected ) engines have a single carburetor and a matching intake manifold that divides and transports the air fuel mixture to the intake valves, though some engines (like motorcycle engines) use multiple carburetors on split heads. Multiple carburetor engines were also common enhancements for modifying engines in the USA from the 1950s to mid-1960s, as well as during the following decade of high- performance muscle cars fueling different chambers of the engine's intake manifold .
Older engines used updraft carburetors, where the air enters from below the carburetor and exits through the top. This had the advantage of never "flooding" the engine, as any liquid fuel droplets would fall out of the carburetor instead of into the intake manifold ; it also lent itself to use of an oil bath air cleaner, where a pool of oil below a mesh element below the carburetor is sucked up into the mesh and the air is drawn through the oil-covered mesh; this was an effective system in a time when paper air filters did not exist.
Beginning in the late 1930s, downdraft carburetors were the most popular type for automotive use in the United States. In Europe, the sidedraft carburetors replaced downdraft as free space in the engine bay decreased and the use of the SU-type carburetor (and similar units from other manufacturers) increased. Some small propeller-driven aircraft engines still use the updraft carburetor design. The main disadvantage of basing a carburetor's operation on Bernoulli's principle is that, being a fluid dynamic device, the pressure reduction in a venturi tends to be proportional to the square of the intake air speed. The fuel jets are much smaller and limited mainly by viscosity, so that the fuel flow tends to be proportional to the pressure difference. So jets sized for full power tend to starve the engine at lower speed and part throttle. Most commonly   this has been corrected by using multiple jets. In SU and other movable jet carburetors, it was corrected by varying the jet size. For cold starting, a different principle was used in multi-jet carburetors. A flow resisting valve called a choke, similar to the throttle valve, was placed upstream of the main jet to reduce the intake pressure and suck additional fuel out of the jets.
Operation
Fixed- venturi, in which the varying air velocity in the venturi alters the fuel flow; this architecture is employed in most carburetors found on cars.
Variable-venturi , in which the fuel jet opening is varied by the slide (which simultaneously alters air flow). In "constant depression" carburetors, this is done by a vacuum operated piston connected to a tapered needle which slides inside the fuel jet. A simpler version exists, most commonly found on small motorcycles and dirt bikes, where the slide and needle is directly controlled by the throttle position. The most common variable venturi (constant depression) type carburetor is the sidedraft SU carburetor and similar models from Hitachi, Zenith-Stromberg and other makers. The UK location of
the SU and Zenith -Stromberg companies helped these  arburetors rise to a position of domination in the UK car market, though such carburetors were also very widely used on Volvos and other non-UK makes.
Other similar designs have been used on some European and a few Japanese automobiles. These carburetors are also referred to as "constant velocity" or "constant vacuum" carburetors. An interesting variation was Ford's VV (Variable Venturi) carburetor, which was essentially a fixed venturi carburetor with one side of the venturi hinged and movable to give a narrow throat at low rpm
and a wider throat at high rpm. This was designed to provide good mixing and airflow over a range of engine speeds, though the VV carburetor proved problematic in service.
A high performance 4-barrel carburetor. Under all engine operating conditions, the carburetor must: Measure the airflow of the engine Deliver the correct amount of fuel to keep the fuel/air mixture in the proper range (adjusting for factors such as temperature)
Mix the two finely and evenly
This job would be simple if air and gasoline (petrol) were ideal fluids; in practice, however, their deviations from ideal behavior due to viscosity, fluid drag, inertia, etc. require a great deal of complexity to compensate for exceptionally high or low engine speeds. A carburetor must provide the proper fuel/air mixture across a wide range of ambient temperatures, atmospheric pressures, engine speeds and loads, and centrifugal forces :
Cold start
Hot start
Idling or slow-running
Acceleration
High speed / high power at full throttle
Cruising at part throttle (light load)
In addition, modern carburetors are required to do this while maintaining low rates of exhaust emissions . To function correctly under all these conditions, most carburetors contain a complex set of mechanisms to support several different operating modes, called circuits.
Basics Cross-sectional schematic of a downdraft carburetor
A carburetor basically consists of an open pipe through which the air passes into the inlet manifold of the engine. The pipe is in the form of a venturi: it narrows in section and then widens again, causing the airflow to increase in speed in the narrowest part. Below the venturi is a butterfly valve called the throttle valve — a rotating disc that can be turned end-on to the airflow, so as to hardly restrict the flow at all, or can be rotated so that it (almost) completely blocks the flow of air. This valve controls the flow of air through the carburetor throat and thus the quantity of air/fuel mixture the system will deliver, thereby regulating engine power and speed. The throttle is connected, usually through a cable or a mechanical linkage of rods and joints or rarely by pneumatic link , to the accelerator pedal on a car or the equivalent control on other vehicles or equipment.
Fuel is introduced into the air stream through small holes at the narrowest part of the venturi and at other places where pressure will be lowered when not running on full throttle. Fuel flow is adjusted by means of precisely calibrated orifices, referred to as jets , in the fuel path.
Off-idle circuit
As the throttle is opened up slightly from the fully closed position, the throttle plate uncovers additional fuel delivery holes behind the throttle plate where there is a low pressure area created by the throttle plate blocking air flow; these allow more fuel to flow as well as compensating for the reduced vacuum that occurs when the throttle is opened, thus smoothing the transition to metering fuel flow through the regular open throttle circuit.
Main open-throttle circuit
As the throttle is progressively opened, the manifold vacuum is lessened since there is less restriction on the airflow, reducing the flow through the idle and off-idle circuits. This is where the venturi shape of the carburetor throat comes into play, due to Bernoulli's principle (i.e., as the velocity increases, pressure falls). The venturi raises the air velocity, and this high speed and thus low pressure sucks fuel into the airstream through a nozzle or nozzles located in the center of the venturi. Sometimes one or more additional booster venturis are placed coaxially within the primary venturi to increase the effect.
As the throttle is closed, the airflow through the venturi drops until the lowered pressure is insufficient to maintain this fuel flow, and the idle circuit takes over again, as described above.
Bernoulli's principle, which is a function of the velocity of the fluid, is a dominant effect for large openings and large flow rates, but since fluid flow at small scales and low speeds (low Reynolds number ) is dominated by viscosity, Bernoulli's principle is ineffective at idle or slow running and in the very small carburetors of the smallest model engines. Small model engines have flow restrictions ahead of the jets to reduce the pressure enough to suck the fuel into the air flow. Similarly the idle and slow running jets of large carburetors are placed after the throttle valve where the pressure is reduced partly by viscous drag, rather than by Bernoulli's principle. The most common rich mixture
device for starting cold engines was the choke, which works on the same principle.
Power valve
For open throttle operation a richer mixture will produce more power, prevent pre-ignition detonation , and keep the engine cooler. This is usually addressed with a spring- loaded "power valve", which is held shut by engine vacuum. As the throttle opens up, the vacuum decreases and the spring opens the valve to let more fuel into the main circuit. On two-stroke engines , the operation of the power valve is the reverse of normal — it is normally "on" and at a set rpm it is turned "off". It is activated at high rpm to extend the engine's rev range, capitalizing on a two-stroke's tendency to rev higher momentarily when the mixture is lean.

Alternative to employing a power valve, the carburetor may utilize a metering rod or step-up rod system to enrich the fuel mixture under high-demand conditions. Such systems were originated by Carter Carburetor [citation needed] in the 1950s for the primary two venturis of their four barrel carburetors, and step-up rods were widely used on most 1-, 2-, and 4-barrel Carter carburetors through the end of production in the 1980s. The step-up rods are tapered at the bottom end, which extends into the main metering jets. The tops of the rods are connected to a vacuum piston and/or a mechanical linkage which lifts the rods out of the main jets when the throttle is opened (mechanical linkage) and/or when manifold vacuum drops (vacuum piston). When the step-up rod is lowered into the main jet, it restricts the fuel flow. When the step-up rod is raised out of the jet, more fuel can flow through it. In this manner, the amount of fuel delivered is tailored to the transient demands of the engine. Some 4-barrel carburetors use metering rods only on the primary two venturis, but some use them on both primary and secondary circuits, as in the Rochester Quadrajet.
Accelerator pump
Liquid gasoline, being denser than air, is slower than air to react to a force applied to it. When the throttle is rapidly opened, airflow through the carburetor increases immediately, faster than the fuel flow rate can increase. This transient oversupply of air causes a lean mixture, which makes the engine misfire (or "stumble")—an effect opposite what was demanded by opening the throttle. This is remedied by the use of a small piston or diaphragm pump which, when actuated by the throttle linkage, forces a small amount of gasoline through a jet into the carburetor throat. [10] This extra shot of fuel counteracts the transient lean condition on throttle tip-in.
Most accelerator pumps are adjustable for volume and/or duration by some means. Eventually the seals around the moving parts of the pump wear such that pump output is reduced; this reduction of the accelerator pump shot causes stumbling under acceleration until the seals on the pump are renewed. The accelerator pump is also used to prime the engine with fuel prior to a cold start. Excessive priming, like an improperly adjusted choke, can cause flooding . This is when too much fuel and not enough air are present to support combustion. For this reason, most carburetors are equipped with an unloader mechanism: The accelerator is held at wide open throttle while the engine is cranked, the unloader holds the choke open and admits extra air, and eventually the excess fuel is cleared out and the engine starts.
Choke
When the engine is cold, fuel vaporizes less readily and tends to condense on the walls of the intake manifold, starving the cylinders of fuel and making the engine difficult to start; thus, a richer mixture (more fuel to air) is required to start and run the engine until it warms up. A richer mixture is also easier to ignite.
To provide the extra fuel, a choke is typically used; this is a device that restricts the flow of air at the entrance to the carburetor, before the venturi. With this restriction in place, extra vacuum is developed in the carburetor barrel, which pulls extra fuel through the main metering system to supplement the fuel being pulled from the idle and off-idle circuits. This provides the rich mixture required to sustain operation at low engine temperatures.
In addition, the choke can be connected to a cam (the fast idle cam) or other such device which prevents the throttle plate from closing fully while the choke is in operation. This causes the engine to idle at a higher speed. Fast idle serves as a way to help the engine warm up quickly, and give a more stable idle while cold by increasing airflow throughout the intake system which helps to better atomize the cold fuel.
In many carbureted cars, the choke is controlled by a cable connected to a pull-knob on the dashboard operated by the driver. In some carbureted cars it is automatically controlled by a thermostat employing a bimetallic spring , which is exposed to engine heat, or to an electric heating element. This heat may be transferred to the choke thermostat via simple convection, via engine coolant, or via
air heated by the exhaust. More recent designs use the engine heat only indirectly: A sensor detects engine heat and varies electrical current to a small heating element, which acts upon the bimetallic spring to control its tension, thereby controlling the choke. A choke unloader is a linkage arrangement that forces the choke open against its spring when the vehicle's accelerator is moved to the end of its travel. This provision allows a "flooded" engine to be cleared out so that it will start.
Some carburetors do not have a choke but instead use a mixture enrichment circuit, or enrichment. Typically used on small engines, notably motorcycles, enrichments work by opening a secondary fuel circuit below the throttle valves. This circuit works exactly like the idle circuit, and when engaged it simply supplies extra fuel when the throttle is closed.
Classic British motorcycles, with side-draft slide throttle carburetors, used another type of "cold start device", called a "tickler". This is simply a spring-loaded rod that, when depressed, manually pushes the float down and allows excess fuel to fill the float bowl and flood the intake tract. If the "tickler" is held down too long it also floods the outside of the carburetor and the crankcase below, and is therefore a fire hazard.
Other elements The interactions between each circuit may also be affected by various mechanical or air pressure connections and also by temperature sensitive and electrical components. These are introduced for reasons such as response, fuel efficiency or automobile emissions control . Various air
bleeds (often chosen from a precisely calibrated range, similarly to the jets) allow air into various portions of the fuel passages to enhance fuel delivery and vaporization. Extra refinements may be included in the carburetor/ manifold combination, such as some form of heating to aid fuel vaporization such as an early fuel evaporator .
Fuel supply
Float chamber
Holley "Visi-Flo" model #1904 carburetors from the 1950s, factory equipped with transparent glass bowls. To ensure a ready mixture, the carburetor has a "float chamber" (or "bowl") that contains a quantity of fuel at near-atmospheric pressure, ready for use. This reservoir is constantly replenished with fuel supplied by a fuel pump . The correct fuel level in the bowl is maintained by means of a float controlling an inlet valve , in a manner very similar to that employed in a cistern (e.g. a toilet tank).
As fuel is used up, the float drops, opening the inlet valve and admitting fuel. As the fuel level rises, the float rises and closes the inlet valve. The level of fuel maintained in the float bowl can usually be adjusted, whether by a setscrew or by something crude such as bending the arm to which the float is connected. This is usually a critical adjustment, and the proper adjustment is indicated by lines inscribed into a window on the float bowl, or a measurement of how far the float hangs below the top of the carburetor when disassembled, or similar.
Floats can be made of different materials, such as sheet brass soldered into a hollow shape, or of plastic; hollow floats can spring small leaks and plastic floats can eventually become porous and lose their flotation; in either case the float will fail to float, fuel level will be too high, and the engine will not run unless the float is replaced. The valve itself becomes worn on its sides by its motion in its "seat" and will eventually try to close at an angle, and thus fails to shut off the fuel completely; again, this will cause excessive fuel flow and poor engine operation.
Conversely, as the fuel evaporates from the float bowl, it leaves  sediment, residue, and varnishes behind, which clog the passages and can interfere with the float operation. This is particularly a problem in automobiles operated for only part of the year and left to stand with full float chambers for months at a time; commercial fuel stabilizer additives are available that reduce this problem.
The fuel stored in the chamber (bowl) can be a problem in hot climates. If the engine is shut off while hot, the temperature of the fuel will increase, sometimes boiling ("percolation"). This can result in flooding and difficult or impossible restarts while the engine is still warm, a phenomenon known as "heat soak". Heat deflectors and insulating gaskets attempt to minimize this effect. The Carter Thermo-Quad carburetor has float chambers manufactured of insulating plastic (phenolic), said to keep the fuel twenty degrees (F.) cooler.
Usually, special vent tubes allow atmospheric pressure to be maintained in the float chamber as the fuel level changes; these tubes usually extend into the carburetor  throat. Placement of these vent tubes is critical to prevent fuel from sloshing out of them into the carburetor, and sometimes they are modified with longer tubing. Note that this leaves the fuel at atmospheric pressure, and therefore it cannot travel into a throat which has been pressurized by a supercharger mounted upstream; in such cases, the  entire carburetor must be contained in an airtight pressurized box to operate. This is not necessary in  installations where the carburetor is mounted upstream of the supercharger, which is for this reason the more frequent system. However, this results in the supercharger being filled with compressed fuel/air mixture, with a strong tendency to explode should the engine backfire ; this type of explosion is frequently seen in drag races, which for safety reasons now incorporate pressure releasing blow-off plates on the intake manifold, breakaway bolts holding the supercharger to the manifold, and shrapnel-catching ballistic nylon blankets surrounding the superchargers.
Diaphragm chamber
If the engine must be operated in any orientation (for example a chain saw ), a float chamber is not suitable. Instead, a diaphragm chamber is used. A flexible diaphragm forms one side of the fuel chamber and is arranged so that as fuel is drawn out into the engine, the diaphragm is forced inward by ambient air pressure. The diaphragm is connected to the needle valve and as it moves inward it opens the needle valve to admit more fuel, thus replenishing the fuel as it is consumed. As fuel is
replenished the diaphragm moves out due to fuel pressure and a small spring, closing the needle valve. A balanced state is reached which creates a steady fuel reservoir level, which remains constant in any orientation.

Carrier as Mechanical Engineer

Introduction
Mechanical engineering is one of the oldest branches of engineering. It is also referred to as the ‘mother’ branch of engineering. Another appealing feature of mechanical engineering is that the application base of this field of study is extremely broad and diverse. Almost all inventions during the ancient period and a vast majority in the modern era are direct contributions of one or the other application of mechanics.
Traditionally, mechanical engineers have to deal with concepts such as mechanics, thermodynamics, robotics, kinematics, structural analysis, fluid mechanics and many others. These concepts are applied in the process of designing state-of-the-art manufacturing units, different types of motor vehicles, aircraft and aerospace parts and a vast assortment of industrial machinery. Mechanical engineers also contribute in the development of various engines, power plant equipment, heating and cooling systems and other simple and complex machinery.
Mechanical engineers not only design new mechanical systems but they are also responsible for testing, maintaining and manufacturing them. The aforementioned are the conventional roles and responsibilities of mechanical engineers. However, times have changed. Nowadays the scope of mechanical engineering is expanding beyond its traditional boundaries.
Mechanical engineers are focussing their attention towards new areas of research such as nanotechnology, development of composite materials, biomedical applications, environmental conservation, etc. The ever increasing scope of this particular job profile now requires professionals to get into financial and marketing aspects of product development and even into people and resource management. All in all mechanical engineering offers a wide bouquet of job options to students who are looking for a stable and stimulating career.
Step-by-Step
Passing 10+2 with PCM (Physics, Chemistry and Mathematics) is the first step you take towards becoming a professional mechanical engineer. To be eligible for a graduate programme (BE/BTech) in a college, you should have scored at least 50% marks and 60% for being eligible for IITs (Indian Institute of Technology) in 10+2 with PCM as subjects.
After this, you can sit for various entrance examinations such as:
  • • The Joint Entrance Examination for IITs (IIT JEE) for admission to various IITs, NITs, IIITs, and other regional government and private colleges.
  • Another option is state level entrance tests conducted by the state level authorities like WBJEE, JKCET, UPCET, JCET, APCET so  on.
  • Another option is private colleges entrance exam like BITSAT, VITEE, LPUSET, MCET, so on.
Apart from these, there are hundreds of engineering colleges across the length and breadth of the country  where you can get into a graduate programme in mechanical engineering.
You can also opt for a diploma in engineering from a polytechnic. For obtaining a diploma, the basic eligibility is completion of Class 10 with 50% marks. The duration of these diploma courses is three-years for regular and four- years for part-time study.
You can also go for an associate membership qualification from the Institute of Mechanical Engineers, which is considered at par with the diploma earned from a state run polytechnic or a university degree. Another option is to earn a similar qualification offered by the Institution of Engineering (India). Diploma holders can also get direct entry into the second year of a graduate program (lateral entry).
After successful completion of the graduate program, you can go for the two-year masters program in mechanical engineering or ME/MTech. If you are interested in pursuing a post-graduate programme in mechanical engineering from any of the IITs, then you must appear for the Graduate Aptitude Test for Engineers (GATE).
These days many engineering colleges are offering a dual (BE/BTech and ME/MTech) programmes. Some other institutions are offering a combination of an engineering degree along with a management programme. In case you are interested in further studies, you can go do a PhD or even opt for a management degree from a reputed business school.
Start Early
To make mechanical engineering your chosen career path, you must have affinity for the way different machines function. This trait can be observed from early childhood when children try to tinker around with different machinery in their immediate vicinity. Such kids often tend to take apart mechanical toys, clocks, bicycles and then they try to assemble them back again.
These children are so innovative that they may even try to make new things. Here, parents have a  special role to play. They must understand that the child possesses an inquisitive mind that is interested in gaining knowledge about machinery and not in breaking or destroying things. Parents must encourage the child’s curiosity to know more about different gadgets and machines in and  round the house.
During schooling, the quest to play around with machinery increases all the more. This curiosity often culminates with the child opting for science with the PCM subject combination.
Is it the Right Career for Me?
Like other career paths, the entry into this particular branch of engineering also requires you to possess certain basic traits. First and foremost, you must have a penchant for mechanical components and machinery and how these machines work. Then you must be good at physics, chemistry and mathematics. You must also have skills such as an analytical bent of mind, logical reasoning and problem solving.
Further, you must have immense patience, physical strength, ability to work for long hours and an inventive spirit that are essential ingredients for becoming a successful mechanical engineer.
What would it Cost Me?
A graduate programme from a private engineering institution will cost you anywhere between Rs.50,000 to Rs.2,00,000 annually. However, in a reputed government run establishment such as the Indian institute of Technology (IIT) or any regional engineering college, you will have to pay an annual fees in the range of anywhere between Rs 30,000 to Rs 40,000.
Funding/Scholarship
Educational institutes offering programmes in mechanical engineering generally extend scholarships to students from socially and economically backward classes. For example, IITs waive off the complete tuition fees for students belonging to the socially backward communities. Scholarships, freeships, stipends and financial assistance are also provided to students on the basis of merit and other qualifying criteria.
Job Prospect
Since mechanical engineering is the broadest of all engineering fields, the job prospects on offer for skilled mechanical engineers are aplenty and unending. Mechanical engineers are required to design, test, manufacture, install, operate and maintain a wide array of machines and mechanical systems that are used in countless industries. These professionals can find employment both in the government and private sector undertakings.
Major industries that employ mechanical engineers include automobiles, space research, aeronautical, energy and utilities, air conditioning, bio-mechanical industry. Other major employers include giant manufacturing plants, air conditioning and refrigeration industry, turbine manufacturing plants, oil and gas exploration and refining industries and the agricultural sector.
In the government sector, mechanical engineers can provide their knowledge to various government run projects in the role of technical experts and consultants. They can also work in private engineering companies that provide technical consultancy to both government and corporate firms. These engineers can also hold high managerial positions in government as well as private sector organisations according to their field of expertise and educational qualifications.
Pay Packet
Mechanical engineering offers a wide variety of career opportunities to job aspirants. The average monthly salary of mechanical engineers who are new to this profession is approximately in the range between Rs.10,000 and Rs.25,000. Good campus placements can fetch even better packages for deserving students. Mechanical engineers who hold a post-graduate degree from a reputed academic institute tend to get better offers than diploma and degree holders.
From here on the annual pay packet depends on a number of factors such as the skill set possessed, experience, expertise, the employer, nature of roles and responsibilities, etc. Highly skilled mechanical engineers can easily command pay packets as high as Rs 40-45 lacs per annum.
Demand and Supply
There is great deman d for skilled mechanical engineers in different segments of the industry. Their expertise is required in traditional manufacturing industries such as automobiles, aviation, shipping, aerospace, power plants and machinery manufacturing. In recent times, the services of expert mechanical engineers have even been  sought in fields such as nanotechnology, biomedical engineering, energy conservation and environmental engineering.
There is also great requirement for mechanical engineer consultants who have management skills along with  technical proficiency. The primary role of such professionals is to manage both technology and people and firms that provide engineering consultancy require them. Various engineering colleges and polytechnics across the country are doing their best to meet the burgeoning demand of skilled mechanical engineering professionals.
Market Watch
The job market for mechanical engineers is perennial. Even the vagaries of the global economic crisis could not knock out the demand for these professionals in the Indian job market. Although some branches of mechanical engineering went out of focus during the meltdown period, the overall situation was much better as compared with other careers. On the brighter side, things are getting  ack
to normal and this evergreen career path is again gaining coin amongst career aspirants as it did during the pre- meltdown years.
In fact, this is a period of resurgence for mechanical engineers. They not only have countless options in the industrial sector but they can also make foray into new realms of technology and even get into management and technical consultancy.
According to a survey, mechanical engineering is amongst the most sought after branches of engineering preferred by students seeking admission to various technical institutes across India in the recent years.
International Focus
Highly qualified professionals from this field, such as post- graduates from various IITs, often seek suitable employment in foreign countries. It is not that only highly qualified mechanical engineers get opportunity to work abroad. If you are employed in a multinational company, you may also get the chance to work on offshore projects
Positives/Negatives
+ives
• There are umpteen job openings and you will not remain unemployed
• Constant involvement in the development of new components, gadgets and machines
• Innovative contribution to the new frontiers of science such as nanotechnology, biomedical engineering and environmental sciences
• Not hit by recession or global economic meltdown
-ives
• Working conditions can be adverse at times
• Deadlines and work pressure can exact a heavy toll on the body and mind
• Physically strenuous and not for the weak 
Different Roles, Different Names Mechanical engineering is considered the ‘mother’ of all branches of engineering. In this context the roles and responsibilities held by a mechanical engineer are different and depend on their area of specialisation and the industry they are working for. In broad terms, the job profile of mechanical engineers can be classified into the following functional segments:
• Research and Development (R&D): Engineers whose role is to do research and then plan for new machines and their constituent parts.
• Design: Professionals whose responsibility is to draft technical drawings, manually or with the aid of computers.
• Production: Engineers who supervise the manufacturing of mechanical components and machines.
• Analysis and testing: Engineers who analyse and test different types of machines and their parts to ensure that they function flawlessly.
• Installation: Professionals who install machines and mechanical parts at the client location.
• Maintenance: Engineers whose primary role is to ensure that machinery is working as per specifications.
Top Companies
1. Automobile and auto part manufacturers
2. Aerospace industry
3. Various Government sector undertakings
4. Aviation companies
5. Steel plants
6. Thermal plants and gas turbine manufacturers
7. Air conditioning and refrigeration industry
8. Shipping industry
9. Engineering consultancies
10. Armed forces
Tips for Getting Hired
1. It is advisable to earn a post-graduate degree in this field
2. Computer proficiency is a must these days
3. You must have excellent communication and interpersonal skills
4. A management degree further brightens your career prospects