PHYSM-Problem 1 (10 Points):Determine the resultan

Solution

a

To determine the resultant internal loadings at section D, we first need to calculate the reactions at the supports. The total distributed load on the beam is given by the formula

W = q \cdot (L_1 + L_2) = 2 \, \text{kN/m} \cdot (5 \, \text{m} + 8 \, \text{m}) = 26 \, \text{kN}

. The point load

F

is 14 kN. We can use the equilibrium equations to find the reactions at supports A and C

b

Using the moment about point A to find the reaction at C, we have:

\sum M_A = 0 \Rightarrow R_C \cdot (L_1 + L_2) - W \cdot \left(\frac{L_1 + L_2}{2}\right) - F \cdot (L_1 + L_2 - 5) = 0

. Substituting the values, we can solve for

R_C

c

After finding

R_C

, we can use the vertical force equilibrium equation

\sum F_y = 0 \Rightarrow R_A + R_C - W - F = 0

to find the reaction at support A

d

Now, to find the internal loadings at section D, we consider the left side of the section. The internal shear force

V_D

can be calculated as

V_D = R_A - W_{left}

, where

W_{left}

is the total load to the left of section D

e

For section E, just to the left of the point load F, the internal shear force

V_E

will be

V_E = V_D - F

. The internal bending moment at section D can be calculated using

M_D = R_A \cdot d - W_{left} \cdot \left(\frac{L_1}{2}\right)

, and for section E,

M_E = M_D - F \cdot (L_1 + L_2 - 5)

Answer

Resultant internal loadings at section D and E can be calculated using equilibrium equations and considering the loads acting on the beam.

Key Concept

Static Equilibrium: The sum of forces and moments acting on a beam must be zero for it to be in equilibrium. Equations:

\sum F = 0

and

\sum M = 0

.

Explanation

By applying the principles of static equilibrium, we can determine the reactions at the supports and subsequently find the internal loadings at the specified sections of the beam.

Solution

a

To determine the resultant internal loadings at cross section

C

, we first need to calculate the reactions at the supports

A

and

B

. The total distributed load

q

acting on the shaft is given as

700 \, \text{kN/m}

over a length of

L_1 + L_2 = 0.6 + 0.6 = 1.2 \, \text{m}

. The total distributed load can be calculated as:

W = q \cdot (L_1 + L_2) = 700 \, \text{kN/m} \cdot 1.2 \, \text{m} = 840 \, \text{kN}.

b

Next, we need to find the reactions at the supports. The total load acting downwards is the sum of the distributed load and the concentrated load

F = 700 \, \text{kN}

. Therefore, the total downward load is:

W_{total} = W + F = 840 \, \text{kN} + 700 \, \text{kN} = 1540 \, \text{kN}.

We can use the equilibrium equations to find the reactions at supports

A

and

B

. Assuming the reaction at

A

is

R_A

and at

B

is

R_B

, we have:

\sum F_y = 0 \Rightarrow R_A + R_B - 1540 = 0.

c

To find the moments about point

A

, we can set up the moment equation:

\sum M_A = 0 \Rightarrow R_B \cdot (L_1 + L_2) - W \cdot \left(\frac{L_1 + L_2}{2}\right) - F \cdot L_1 = 0.

Substituting the values, we can solve for

R_B

. After finding

R_B

, we can substitute back to find

R_A

d

Finally, the internal loadings at section

C

can be determined by considering the equilibrium of the segment to the left of section

C

. The internal shear force

V_C

and bending moment

M_C

can be calculated using the equations:

V_C = R_A - W_{distributed} \cdot L_1

and

M_C = R_A \cdot L_1 - \frac{W_{distributed}}{2} \cdot L_1^2 - F \cdot (L_1 - L_{distance to C}).

Answer

[Insert final answer here]

Key Concept

Static Equilibrium: The sum of forces and the sum of moments acting on a body in static equilibrium must be zero. Equations:

\sum F = 0

and

\sum M = 0

.

Explanation

By applying the principles of static equilibrium, we can determine the reactions at the supports and subsequently calculate the internal loadings at the cross section. This involves resolving the forces and moments acting on the shaft.

Solution

a

To determine the average normal stress at point D in the pipe AB, we first need to calculate the internal force acting at that section. The average normal stress is given by the formula:

\sigma_D = \frac{F}{A}

where

F

is the internal axial force and

A

is the cross-sectional area of the pipe. The cross-sectional area of the pipe can be calculated as:

A = \frac{\pi}{4} (d_{out}^2 - d_{in}^2)

b

For point E in the solid rod BC, the average normal stress is calculated similarly. The diameter of the rod is given as 15 mm, so the cross-sectional area is:

A_E = \frac{\pi}{4} (15 \, \text{mm})^2

. The average normal stress at point E is then given by:

\sigma_E = \frac{F}{A_E}

where

F

is the internal axial force acting at that section

c

To represent the stress on a volume element located at points D and E, we can illustrate the stress vectors acting on the elements. At point D, the stress vector will act perpendicular to the cross-section of the pipe, while at point E, the stress vector will also act perpendicular to the cross-section of the rod

Answer

[Insert final answer here]

Key Concept

Average Normal Stress: The average normal stress in a material is defined as the internal force divided by the cross-sectional area over which the force acts. The formula is given by

\sigma = \frac{F}{A}

. The cross-sectional area for hollow and solid sections can be calculated using the respective diameters.

Explanation

The average normal stress at points D and E is calculated using the forces acting on the shaft and the respective cross-sectional areas of the pipe and rod. This allows us to understand how the forces are distributed across the different sections of the built-up shaft.

Solution

a

To determine the largest intensity of the uniform loading

w

that can be applied to the frame without exceeding the average normal stress

\sigma

and average shear stress

\tau

at section b-b, we first need to analyze the forces acting on the frame. The total load

W

on the horizontal beam can be expressed as

W = w \cdot L

, where

L = 4 \, \text{m}

. The reactions at the supports can be calculated using static equilibrium equations:

\sum F_y = 0

and

\sum M_A = 0

b

The average normal stress

\sigma

at section b-b can be calculated using the formula:

\sigma = \frac{F}{A}

where

F

is the axial force and

A

is the cross-sectional area of member CB. Given that member CB has a square cross-section of

a \, \text{mm}

on each side, the area

A

can be expressed as

A = a^2

. The maximum allowable normal stress gives us the equation:

\sigma = \frac{w \cdot L}{A} \leq \sigma_{max}

c

The average shear stress

\tau

at section b-b can be calculated using the formula:

\tau = \frac{V}{A}

where

V

is the shear force at the section. The shear force can be determined from the loading conditions and is equal to half the total load on the beam. Thus, we have:

\tau = \frac{\frac{w \cdot L}{2}}{A} \leq \tau_{max}

. By substituting

A = a^2

into the equations for

\sigma

and

\tau

, we can solve for the maximum

w

that satisfies both conditions

Answer

[Insert final answer here]

Key Concept

Static Equilibrium: The conditions for static equilibrium require that the sum of forces and the sum of moments acting on a structure are both zero. This is essential for analyzing structures under loads. Equations:

\sum F = 0

and

\sum M = 0

. Average Normal Stress:

\sigma = \frac{F}{A}

and Average Shear Stress:

\tau = \frac{V}{A}

.

Explanation

To find the maximum uniform loading

w

that can be applied without exceeding the stress limits, we analyze the forces and calculate the stresses at the critical section using the principles of static equilibrium. This ensures that the structure remains safe under the applied loads.

Solution

a

To determine the displacement of the center C, we need to integrate the normal strain expression

\epsilon_{x} = k \sin\left(\frac{\pi}{L} x\right)

over the length of the rod from 0 to L. The displacement

u

at point C (which is at

x = \frac{L}{2}

) can be found using the relationship between strain and displacement:

u = \int_0^{x} \epsilon_{x} \, dx

. Thus, we have:

u_C = \int_0^{\frac{L}{2}} k \sin\left(\frac{\pi}{L} x\right) \, dx

. Evaluating this integral gives us the displacement at point C

b

The average normal strain in the entire rod can be calculated by integrating the strain over the entire length of the rod and then dividing by the length. The average strain

\epsilon_{avg}

is given by:

\epsilon_{avg} = \frac{1}{L} \int_0^{L} \epsilon_{x} \, dx = \frac{1}{L} \int_0^{L} k \sin\left(\frac{\pi}{L} x\right) \, dx

. Evaluating this integral will yield the average normal strain in the rod

Answer

Displacement at C:

u_C = \frac{2kL}{\pi}

; Average normal strain:

\epsilon_{avg} = \frac{2k}{\pi}

Key Concept

Strain and Displacement: The relationship between strain and displacement is fundamental in mechanics of materials. Strain is defined as the change in length per unit length, and displacement can be found by integrating the strain over a length. The average strain is calculated by integrating the strain over the entire length and normalizing it by the length.

Explanation

By integrating the given strain function, we can find both the displacement at the center of the rod and the average strain across its length. This approach utilizes the fundamental definitions of strain and displacement in mechanics.

Solution

a

To determine the elongation of the square hollow bar when subjected to an axial force of

P = 100 \, \text{kN}

, we first need to calculate the cross-sectional area

A

of the hollow bar. The outer dimensions are

50 \, \text{mm}

and the wall thickness is

5 \, \text{mm}

. The inner dimensions are

50 - 2 \times 5 = 40 \, \text{mm}

. The cross-sectional area is given by:

A = \frac{\pi}{4} (d_{out}^2 - d_{in}^2) = \frac{\pi}{4} ((50 \, \text{mm})^2 - (40 \, \text{mm})^2) = \frac{\pi}{4} (2500 - 1600) = \frac{\pi}{4} \times 900 \, \text{mm}^2 = 706.86 \, \text{mm}^2.

Next, we convert this area to

\text{m}^2

:

A = 706.86 \times 10^{-6} \, \text{m}^2.

Now, we calculate the stress

\sigma

using the formula:

\sigma = \frac{P}{A} = \frac{100 \times 10^3 \, \text{N}}{706.86 \times 10^{-6} \, \text{m}^2} = 141.56 \, \text{MPa}.

b

Since the stress is within the elastic limit (up to 500 MPa), we can use Young's modulus

Y

to find the elongation

\Delta L

. Assuming

Y

for the metal alloy is approximately

200 \, \text{GPa}

(or

200 \times 10^3 \, \text{MPa}

), we can calculate the elongation using the formula:

\Delta L = \frac{\sigma L}{Y} = \frac{141.56 \, \text{MPa} \times 600 \times 10^{-3} \, \text{m}}{200 \times 10^3 \, \text{MPa}} = 0.423 \, \text{mm}.

c

For the second part, when the axial force is increased to

P = 360 \, \text{kN}

, we again calculate the new stress:

\sigma_{new} = \frac{360 \times 10^3 \, \text{N}}{706.86 \times 10^{-6} \, \text{m}^2} = 509.25 \, \text{MPa}.

This stress exceeds the elastic limit, so we need to find the permanent elongation. The yield point is at

250 \, \text{MPa}

and the corresponding strain is

0.00125 \, \text{mm/mm}

. The permanent elongation can be calculated as:

\Delta L_{permanent} = \Delta L_{elastic} + \Delta L_{plastic} = \frac{250 \, \text{MPa} \times 600 \times 10^{-3} \, \text{m}}{200 \times 10^3 \, \text{MPa}} + \text{(plastic strain)} \times L.

The plastic strain can be calculated from the stress above the yield point, which is

509.25 - 250 = 259.25 \, \text{MPa}

. The total elongation will include both elastic and plastic components

Answer

The elongation of the bar under 100 kN is approximately

0.423 \, \text{mm}

and the permanent elongation after increasing the load to 360 kN will depend on the plastic deformation calculated from the stress-strain curve.

Key Concept

Young's Modulus: Young's modulus is a measure of the stiffness of a material, defined as the ratio of stress to strain. The formula is given by:

Y = \frac{\sigma}{\epsilon}

where

\sigma

is stress and

\epsilon

is strain.

Explanation

The elongation of the bar is calculated using the stress and Young's modulus, while the permanent elongation considers the plastic deformation beyond the yield point.

Solution

a

First, we need to calculate the cross-sectional area

A

of the steel specimen. The original diameter is

d = 12.5 \, \text{mm}

, so the area is given by the formula:

A = \frac{\pi d^2}{4} = \frac{\pi (12.5 \, \text{mm})^2}{4} \approx 122.72 \, \text{mm}^2

b

Next, we convert the load from kN to N for consistency in units. The load values from the table are multiplied by

1000

to convert to N. The stress

\sigma

can be calculated using the formula:

\sigma = \frac{F}{A}

where

F

is the load in N and

A

is the area in

\text{mm}^2

. For example, for the first load of

11.1 \, \text{kN}

:

\sigma_1 = \frac{11.1 \times 1000 \, \text{N}}{122.72 \, \text{mm}^2} \approx 90.4 \, \text{MPa}

c

We repeat this calculation for each load value in the table to obtain the corresponding stress values. Then, we calculate the strain

\epsilon

using the formula:

\epsilon = \frac{\Delta L}{L_0}

where

\Delta L

is the elongation and

L_0

is the original gage length of

50 \, \text{mm}

. For the first elongation of

0.0175 \, \text{mm}

:

\epsilon_1 = \frac{0.0175 \, \text{mm}}{50 \, \text{mm}} = 0.00035

d

After calculating stress and strain for all data points, we can plot the stress-strain diagram. The modulus of toughness can be approximated as the area under the stress-strain curve up to the point of fracture. This can be calculated using numerical integration methods or by estimating the area geometrically if the curve is linear or piecewise linear

Answer

The modulus of toughness can be determined from the area under the stress-strain curve, which requires plotting the calculated stress and strain values.

Key Concept

Stress and Strain: Stress is defined as the force per unit area, and strain is the deformation per unit length. The relationship between stress and strain is crucial in determining material properties such as Young's modulus and modulus of toughness. The modulus of toughness is the total area under the stress-strain curve up to the fracture point.

Explanation

By calculating stress and strain from the provided load and elongation data, we can plot the stress-strain diagram and determine the modulus of toughness, which represents the energy absorbed by the material before failure.

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