Strength of Materials Questionbank

Strength of Materials

For an axial member, the formula for normal stress (\(\sigma\)) is given by:

• \(\sigma = F \cdot A\)
• \(\sigma = \frac{F}{A}\)
• \(\sigma = \frac{M \cdot c}{I}\)
• \(\sigma = \frac{V \cdot Q}{I \cdot t}\)

Explanation:

• Stress is force per unit area, making \(\sigma = F \cdot A\) incorrect as it is force times area.
• \(\sigma = \frac{F}{A}\) is the correct formula for normal (axial) stress.
• \(\sigma = \frac{M \cdot c}{I}\) is the flexure formula for bending stress, not axial stress.
• \(\sigma = \frac{V \cdot Q}{I \cdot t}\) is the formula for shear stress in beams.

The bending stress at a point in a beam is zero. This point is most likely:

• At the top surface of the beam
• At the bottom surface of the beam
• At the neutral axis
• Where the shear force is maximum

Explanation:

• Top and bottom surfaces experience the maximum bending stress (tension or compression).
• The neutral axis is the layer within the beam where the stress transitions from tension to compression; the longitudinal strain and stress are zero here.
• The location of maximum shear force is unrelated to where bending stress is zero.

The state of stress at a point is defined by the components \(\sigma_x = 100 MPa\), \(\sigma_y = -40 MPa\), and \(\tau_{xy} = 50 MPa\). What is the maximum in-plane shear stress (\(\tau_{max}\)) at this point?

• 50 MPa
• 70 MPa
• 86 MPa
• 140 MPa

Explanation:

• The formula for maximum in-plane shear stress is: \(\tau_{max} = \sqrt{ \left( \frac{\sigma_x – \sigma_y}{2} \right)^2 + \tau_{xy}^2 }\)
• Plugging in the values: \(\tau_{max} = \sqrt{ \left( \frac{100 – (-40)}{2} \right)^2 + (50)^2 } = \sqrt{ (70)^2 + (50)^2 } = \sqrt{4900 + 2500} = \sqrt{7400} \approx 86.02 MPa\)
• Therefore, the correct answer is approximately 86 MPa.

Which stress transformation equation is used to find the principal stresses?

• The equation for maximum shear stress
• The equation for normal stress on a plane defined by angle \(\theta\)
• The equation for the center of Mohr’s circle
• The von Mises yield criterion equation

Explanation:

• Principal stresses are the maximum and minimum normal stresses at a point.
• They are found by maximizing/minimizing the normal stress transformation equation: \(\sigma_{n} = \frac{\sigma_x + \sigma_y}{2} + \frac{\sigma_x – \sigma_y}{2} \cos 2\theta + \tau_{xy} \sin 2\theta\).
• The other options are related to different concepts in stress analysis.

According to the Maximum Distortion Energy (von Mises) Theory, yielding begins when:

• The maximum normal stress reaches the yield strength
• The maximum shear stress reaches the shear yield strength
• The distortion energy per unit volume equals the distortion energy per unit volume in a tensile test at yield
• The strain energy per unit volume reaches a critical value

Explanation:

• The first option describes the Maximum Normal Stress theory.
• The second option describes the Tresca (Maximum Shear Stress) theory.
• The von Mises criterion is based on the energy associated with the change in shape (distortion) of the material, not the volume change.
• The final option describes the Total Strain Energy theory, which is different.

Within the elastic limit, the slope of the stress-strain curve for a material represents its:

• Proof Resilience
• Factor of Safety
• Modulus of Elasticity
• Thermal Stress

Explanation:

• Proof Resilience is the maximum strain energy stored without permanent deformation.
• Factor of Safety is the ratio of ultimate stress to working stress.
• According to Hooke’s Law, \( \sigma = E \epsilon \), the modulus of elasticity (E) is the constant of proportionality, which is the slope of the linear stress-strain curve.
• Thermal stress is the stress induced due to restriction of thermal expansion or contraction.

The total area under the engineering stress-strain curve up to the point of fracture represents:

• Modulus of Resilience
• Proof Resilience
• Toughness
• Factor of Safety

Explanation:

• Modulus of Resilience is the area under the curve only up to the elastic limit.
• Proof Resilience is the total strain energy up to the elastic limit.
• Toughness is the ability of a material to absorb energy and plastically deform without fracturing. It is measured by the total area under the stress-strain curve.
• Factor of Safety is a design parameter, not a material property derived from the stress-strain diagram.

A steel rod is heated from 20°C to 80°C but is completely constrained from expanding. The stress developed in the rod is:

• Tensile
• Zero
• Compressive
• Shear

Explanation:

• The rod tries to expand due to heating (\( \delta_{thermal} = \alpha L \Delta T \)).
• Since the ends are fixed, this expansion is fully restricted.
• The supports exert a force on the rod to keep it at its original length, effectively compressing it and generating compressive stress (\( \sigma_{thermal} = E \alpha \Delta T \)).

The Factor of Safety is defined as the ratio of:

• Working stress to Ultimate stress
• Strain energy to Proof resilience
• Yield stress (or Ultimate stress) to Working stress
• Thermal stress to Strain energy

Explanation:

• It is a factor that provides a safety margin against failure.
• It is calculated as \( \text{Factor of Safety} = \frac{\text{Yield Stress}}{\text{Working Stress}} \) or \( \frac{\text{Ultimate Stress}}{\text{Working Stress}} \), ensuring the working stress is well below the failure stress.
• The other options incorrectly define the ratio.

The strain energy per unit volume stored in a material when strained within its elastic limit is known as:

• Toughness
• Proof Resilience
• Modulus of Resilience
• Thermal Stress

Explanation:

• Toughness is the total energy per unit volume up to fracture.
• Proof Resilience is the total strain energy stored up to the elastic limit.
• Modulus of Resilience is the strain energy per unit volume, which is the area under the stress-strain curve up to the proportional limit. It is given by \( U = \frac{\sigma_y^2}{2E} \).

On a stress-strain diagram, the point beyond which the material will not return to its original shape upon unloading is called the:

• Proportional Limit
• Ultimate Tensile Strength
• Yield Point
• Fracture Point

Explanation:

• The Proportional Limit is the point where stress-strain linearity ends, but the material may still be elastic.
• The Ultimate Tensile Strength is the maximum stress on the curve.
• The Yield Point is the stress level at which a material begins to deform plastically. Deformation beyond this point is permanent.
• The Fracture Point is where the material breaks.

For a bar of cross-sectional area A, length L, and modulus of elasticity E, subjected to an axial load P, the expression for strain energy (U) stored is:

• \( U = \frac{P L}{A E} \)
• \( U = \frac{P^2 L}{2 A E} \)
• \( U = \frac{\sigma \epsilon}{2} \)
• \( U = \frac{A E \delta}{L} \)

Explanation:

• The first option \( \frac{P L}{A E} \) is the formula for deflection (δ), not energy.
• The formula for strain energy stored in a linearly elastic body is \( U = \frac{P^2 L}{2 A E} \) or equivalently \( U = \frac{A E \delta^2}{2 L} \).
• The third option \( \frac{\sigma \epsilon}{2} \) is for strain energy per unit volume, not total energy.
• The fourth option is incorrect.

For a simply supported beam with a uniformly distributed load (UDL) of intensity \( w \) over its entire length \( L \), what is the maximum bending moment?

• \( \frac{wL}{2} \)
• \( \frac{wL^2}{8} \)
• \( \frac{wL^2}{2} \)
• \( wL \)

Explanation:

• \( \frac{wL}{2} \) is the value of the maximum shear force, not the bending moment.
• \( \frac{wL^2}{8} \) is the correct formula for the maximum bending moment at the mid-span of a simply supported beam carrying a UDL.
• \( \frac{wL^2}{2} \) is the maximum bending moment for a cantilever beam with a UDL.
• \( wL \) is the total load on the beam.

The point on a beam’s bending moment diagram where the bending moment changes sign (from positive to negative or vice versa) is called a:

• Maximum moment point
• Inflection point
• Point of contraflexure
• Fixed point

Explanation:

• A maximum moment point is where the bending moment is at its highest value.
• An inflection point is a concept in mathematics where the curvature changes.
• A point of contraflexure is the specific term in structural engineering for the point in a beam (like a continuous or fixed beam) where the bending moment is zero and changes sign.
• A fixed point refers to a support condition, not a point on the diagram.

The torsion formula for a circular shaft is given by \( \frac{T}{J} = \frac{\tau}{r} = \frac{G\theta}{L} \). What does the term \( J \) represent?

• Shear Modulus
• Polar Radius
• Polar Moment of Inertia
• Torque

Explanation:

• Shear Modulus is represented by \( G \) in the formula.
• Polar Radius is represented by \( r \), the distance from the center.
• Polar Moment of Inertia (\( J \)) is a geometric property that measures a shaft’s resistance to twisting. For a solid shaft of radius \( R \), \( J = \frac{\pi R^4}{2} \).
• Torque is represented by \( T \).

For a thin cylindrical shell subjected to an internal pressure \( p \), with diameter \( D \) and thickness \( t \), the circumferential (hoop) stress is given by:

• \( \frac{pD}{t} \)
• \( \frac{pD}{2t} \)
• \( \frac{pD}{4t} \)
• \( \frac{2pD}{t} \)

Explanation:

• \( \frac{pD}{t} \) is incorrect and would overestimate the stress.
• \( \frac{pD}{2t} \) is the correct formula for the hoop stress, which is the largest stress and acts circumferentially.
• \( \frac{pD}{4t} \) is the formula for the longitudinal stress in a thin cylinder.
• \( \frac{2pD}{t} \) is incorrect and would greatly overestimate the stress.

In a fixed beam with a point load at the center, how many points of contraflexure are typically present?

• 0
• 1
• 2
• 4

Explanation:

• 0 is the case for a cantilever or a simply supported beam without a moment change.
• 1 is atypical for a fixed beam under a central point load.
• 2 points of contraflexure exist in a fixed beam with a central load. These are the points where the bending moment diagram crosses the zero axis, located between the supports and the center.
• 4 is an incorrect number for this loading condition.

The stiffness of a helical spring is given by \( k = \frac{Gd^4}{8D^3N} \). If the wire diameter \( d \) is doubled, the stiffness becomes:

• Half
• Double
• Four times
• Sixteen times

Explanation:

• Half would be if stiffness was inversely proportional to \( d \).
• Double would be if stiffness was proportional to \( d \).
• Four times would be if stiffness was proportional to \( d^2 \).
• The stiffness \( k \) is proportional to \( d^4 \). If \( d \) is doubled (i.e., becomes \( 2d \)), the new stiffness is \( k_{new} \propto (2d)^4 = 16d^4 \). Therefore, it becomes 16 times the original stiffness.