Best Mechanical Engineering Interview Questions Part – 14
Define Ductility.
Answer:
It is the property of the material enabling it to be drawn into wire, with the application of tensile force. It must be both strong and plastic. It is usually measured in terms of percentage elongation and reduction in area, (e.g.) Ni, Al, and Cu.
Define fatigue.
Answer:
When a material is subjected to repeated stress, it fails at stresses below the yield point stress; such type of failure of the material is called fatigue.
Define: Factor of safety.
Answer:
The ratio between maximum stresses to working stress is known as factor of safety.
Factor of safety = Maximum stress /Working stress
Define endurance limit.
Answer:
Endurance limit is the maximum value of completely reversed stress that the standard specimen can sustain an infinite number (106) of cycles without failure.
What is impact load?
Answer:
If the time of load application is less than one third of the lowest natural period of vibration of the part, it is called an impact load.
What are the various phases of design process?
Answer:
The various phases of design process are:
Recognition of need.
Definition of problem
Synthesis
Analysis and optimization
Evaluation
Presentation
What are the different types of loads that can act on machine components?
Answer:
Different loads on machine components are:
Steady load.
Variable load.
Shock load
Impact load.
What are the factors affecting endurance strength.
Answer:
Factors affecting endurance strength are
Load ii. Surface finish
Size
Temperature
Impact
Reliability
What are the types of variable stresses?
Answer:
Types of variable stresses are:
Completely reversed or cyclic stresses
Fluctuating stresses
Repeated stresses
Differentiate between repeated stress and reversed stress.
Answer:
Repeated stress refers to a stress varying from zero to a maximum value of same nature.
Reversed stress of cyclic stress varies from one value of tension to the same value of compression.
What are the types of fracture?
Answer:
The two types of fracture are
Ductile fracture
Brittle fracture
Distinguish between brittle fracture and ductile fracture.
Answer:
In brittle fracture, crack growth is up to a small depth of the material.
In ductile fracture large amount of plastic deformation is present to a higher depth.
Define stress concentration and stress concentration factor.
Answer:
Stress concentration is the increase in local stresses at points of rapid change in cross section or discontinuities.
Stress concentration factor is the ratio of maximum stress at critical section to the nominal stress
Explain size factor in endurance strength.
Answer:
Size factor is used to consider the effect of the size on endurance strength. A large size object will have more defects compared to a small one. So, endurance strength is reduced. If K is the size factor, then
Actual endurance strength = Theoretical endurance limit x K
Explain Griffith theory. (Or) State the condition for crack growth.
Answer:
A crack can propagate if the energy release rate of crack is greater than crack resistance.
What are the modes of fracture?
Answer:
The different the modes of fractures are:
Mode I (Opening mode) – Displacement is normal to crack surface.
Mode II (Sliding mode) – Displacement is in the plane of the plate.
Mode III (Tearing mode) – Out of plane shear.
What are the factors to be considered in the selection of materials for a machine element?
Answer:
While selecting a material for a machine element, the following factors are to be considered
Required material properties
Manufacturing ease
Material availability
Cost
What are various theories of failure?
Answer:
The failure theories are:
Maximum principal stress theory.
Maximum shear stress theory.
Maximum principal strain theory.
List out the factors involved in arriving at factor of safety.
Answer:
The factors involved in arriving at factor of safety are:
Material properties
Nature of loads
Presence of localized stresses
Mode of failures
Give some methods of reducing stress concentration.
Answer:
Some of the methods are:
Avoiding sharp corners.
Providing fillets.
Use of multiple holes instead of single hole
Undercutting the shoulder parts.
Explain notch sensitivity. State the relation between stress concentration factor and notch sensitivity.
Answer:
Notch sensitivity (q) is the degree to which the theoretical effect of stress concentration is actually reached.
The relation is, Kf = 1 + q (Kt-1)
What are the factors that affect notch sensitivity?
Answer:
The factors effecting notch sensitivity are:
Material
Notch radius
Size of component
Type of loading
Grain Structure
What is the use of Goodman & Soderberg diagrams?
Answer:
They are used to solve the problems of variable stresses.
Define machinability
Answer:
It is the property of the material, which refers to a relative ease with which a material can be cut. It is measured in a number of ways such as comparing the tool life for cutting different material
What is an S-N Curve?
Answer:
An S- N curve has fatigue stress on ‘Y’ axis and number of loading cycles in ‘X’ axis. It is used to find the fatigue stress value corresponding to a given number of cycles.
What is curved beam?
Answer:
In curved beam the neutral axis does not coincide with the centroidal axis.
Give some example for curved beam.
Answer:
C frame, crane hook
What is principle stress and principle plane?
Answer:
A plane which has no shear stress is called principle plane the corresponding stress is called principle stress.
Write the bending equation.
Answer:
The bending moment equation is, M/I = f/y= E/R,
Where,
M – Bending moment (M is in N-mm)
I – Moment of inertia about centroidal axis (I is in mm⁴)
f – Bending Stress (f is in N/mm²)
y – Distance from neutral axis (y is in mm)
E – Young’s modulus (E is in N/mm²)
R – Radius of curvature (R is in mm)
Write the torsion equation.
Answer:
The torsional equation is, T/J = q/r = GӨ/L
Where,
T – Torsional moment (T is in N-mm)
J – Polar moment of inertia (J is in mm⁴)
q – Shear stress in the element (q is in N/mm²)
r – Distance of element from centre of shaft (r is in mm)
G- Modulus of Rigidity (G is in N/mm²)
Ө – Angle of twist (Ө is in radians)
L – Length of the shaft (L is in mm)