Consider the shaft shown (Figure 1) that has a diameter d = 5.3 cm . The length of each segment is L = 2.2 m and the loads P = 1.5 kN are applied horizontally and vertically as shown. The bearings do not exert a moment on the shaft. Use the following process to calculate the maximum bending stress on a section through the shaft at C. Part A Moment due to the horizontal load Since the section is circular, use the y and z-axes as the principal axes. What is the magnitude of the moment about the z-axis at point C due to effects of the the horizontal load? Express your answer with appropriate units to three signficant figures. View Available Hint(s) |M₂| = Submit μA Value Part B - Moment due to the vertical load Submit O What is the magnitude of the moment about the y-axis at point C due to the effects of the vertical load? Express your answer with appropriate units to three significant figures. ► View Available Hint(s) Units μA |M₂| = Value ? Units ?

Consider the shaft shown (Figure 1) that has a diameter d = 5.3 cm . The length of each segment is L = 2.2 m and the loads P = 1.5 kN are applied horizontally and vertically as shown. The bearings do not exert a moment on the shaft. Use the following process to calculate the maximum bending stress on a section through the shaft at C. Part A Moment due to the horizontal load Since the section is circular, use the y and z-axes as the principal axes. What is the magnitude of the moment about the z-axis at point C due to effects of the the horizontal load? Express your answer with appropriate units to three signficant figures. View Available Hint(s) |M₂| = Submit μA Value Part B - Moment due to the vertical load Submit O What is the magnitude of the moment about the y-axis at point C due to the effects of the vertical load? Express your answer with appropriate units to three significant figures. ► View Available Hint(s) Units μA |M₂| = Value ? Units ?

Elements Of Electromagnetics

7th Edition

ISBN:9780190698614

Author:Sadiku, Matthew N. O.

Publisher:Sadiku, Matthew N. O.

ChapterMA: Math Assessment

Section: Chapter Questions

Problem 1.1MA

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Concept explainers

Combined Loading

Any functioning component, such as machine parts, structural members, pressure vessels, and so on, are all under the influence of more than one force. When anybody is under the influence of more than one force such as shear forces, bending moments, axial forces, torsion, and so on, then such body is said to be under combined loading. A very practical example of combined loading is the crankshaft of an internal combustion engine (IC engine). The crankshaft of the IC engine is under high rpm, which is caused due to the torsional forces. Due to the presence of piston, counterbalances, and internal imbalances, the crankshaft experiences lateral forces and due to the rise in temperature, the crankshaft undergoes thermal expansion, which pulls the crankshaft along the axial direction and lateral direction. The presence of unbalanced loads along the periphery of the crankshaft also induces a bending moment.

Question

Figure
X
A
P
P
NE
Z
B
L
с
1 of 1
Part C-Maximum bending stress
Use the results of Part A and Part B to calculate the magnitude of the maximum bending stress at point C.
Express your answer with appropriate units to three significant figures.
► View Available Hint(s)
|σmax| =
Submit
μA
Value
Return to Assignment
Units
Provide Feedback
?

Consider the shaft shown (Figure 1) that has a diameter d = 5.3 cm . The length of each segment is L = 2.2 m and the loads P = 1.5 kN are
applied horizontally and vertically as shown. The bearings do not exert a moment on the shaft. Use the following process to calculate the
maximum bending stress on a section through the shaft at C.
Part A - Moment due to the horizontal load
Since the section is circular, use the y and z-axes as the principal axes. What is the magnitude of the moment about the z-axis at point C
due to effects of the the horizontal load?
Express your answer with appropriate units to three signficant figures.
► View Available Hint(s)
|M₂| =
Submit
☐
|M₂| =
Submit
O
μA
Value
Part B - Moment due to the vertical load
What is the magnitude of the moment about the y-axis at point C due to the effects of the vertical load?
Express your answer with appropriate units to three significant figures.
View Available Hint(s)
☐
Units
μᾶ
Value
?
Units
?

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