**Problem 2:** A concentrated load \( P = 36 \, \text{kN} \) is applied to the upper end of a pipe. The outside diameter of the pipe is \( D = 220 \, \text{mm} \), and the inside diameter is \( d = 200 \, \text{mm} \). Determine the vertical shear stress on the \( y \text{-} z \) plane of the pipe wall.**Diagram Explanation:**1. **3D Pipe Diagram:** - Shows a vertical pipe with a force of 36 kN applied horizontally at the upper end. - Coordinate system with axes labeled \( x \), \( y \), and \( z \) is included.2. **Pipe Cross Section:** - Illustrates a cross-sectional view of the pipe. - Shows the inside diameter \( d = 200 \, \text{mm} \) and the outside diameter \( D = 220 \, \text{mm} \). - The axes \( x \) and \( z \) are indicated to show orientation.The purpose of this problem is to analyze the shear stress developed due to the applied force, focusing on the specific plane of interest.

Given data: concentrated loadP=36 kNoutside diameter of pipeD=220 mminside diameter of piped=200 mm…

Problem 2: A concentrated load P=36 kN is applied to the upper end of a pipe. The outside diameter of the pipe is D = 220 mm, and the inside diameter is d = 200 mm. Determine the vertical shear stress on the y-z plane of the pipe wall. 36 kN DO Pipe cross section. D

Problem 2: A concentrated load P=36 kN is applied to the upper end of a pipe. The outside diameter of the pipe is D = 220 mm, and the inside diameter is d = 200 mm. Determine the vertical shear stress on the y-z plane of the pipe wall. 36 kN DO Pipe cross section. D

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

See similar textbooks

Related questions

Q: Neglecting the weight of the bracket, calculate the three principal stresses, and absolute maximum…

Q: A prismatic steel bar of square cross section 3 in. x 3 in. is subjected to a tensile load P = 135…

A: Solution: Given Data: P=135 kipsAn=6 in2θ=45o

Q: The beam shown below has a cross section of channel shape with width b-400 mm and height h=80 mm,…

A: Answer: (a) The maximum tensile stress is 64.68 MPa. (b) The maximum compressive stress is 16.36…

Q: A cantilever beam with the length of 1.2-m is subjected to a load of P = 400-N. Find: a-The stresses…

A: Given:Length of beam = 1.2mP = 400 NFigure is providedTo find:Stress at K & HTotal tensile or…

Q: For the vertical flexural member shown, determine the maximum shear stress in MPa at section K, as…

Q: The rectangular bar is connected to the support bracket with a 24-mm-diameter pin. The bar width is…

A: Diameter of pin, d=24 mmWidth of the bar, w=80 mmThickness of the bar, t=20 mmDimensions of each…

Q: A typical stainless steel cylindrical vessel is shown. The inside diameter of the tank is 48.0 in.…

Q: 6. The A-frame is loaded by two concentrated forces as shown in the figure. The pins at B and C have…

Q: The rectangular bar is connected to the support bracket with a 10-mm-diameter pin. The bar width is…

Q: Determine the state of stress at point A on the cross section of the beam at section a-a. Take P =…

Q: The bolts in the figure below are being subjected to shear by a vertical reaction. The sheer will…

A: Write the given values using suitable variables. Here F signifies reaction force, D signifies bolt…

Q: Four axially loaded members are shown below. All members have the same value for E (Young’s…

A: There are four cases in which all the components have different cross sectional areas and load and…

Q: I can't seem to find the shear stress at point b. Here's my work for reference.

A: Given-Information: L1=32ftL2=9.3ftL3=14.4ftp=13.5lb/ft2do=9.5int=0.31in To-Determine: Stress at B,…

Q: 20 KN it 80 Q3/ A bracket is supported using 4 rivets having same size, as shown in Figure 3.…

Q: The brace is supported by a bracket as shown below. Calculate the bearing stress at Surface A and…

Q: A compound bar consists of a circular rod of steel of diameter 25 mm, rigidily fitted into a copper…

Q: B = 30° A 50 mm

A: The moment of inertia about the y-axis and z-axis are determined as follows.

Q: = A machine component is fabricated from a bent tube as shown below. One part of the tube lies along…

A: Outside diameter, d0=122 mmInside diameter, di=108 mmForce F=8.5 kNLengths,L1=258 mmL2=118 mmL3=281…

Concept explainers

Axial Load

When a bar of the uniform cross-section is acted by a load, such that the load acts along the longitudinal axis of the bar, such kinds of loadings are known as axial loadings. In general terms, a load is an external force acting on a component. An axial load acts perpendicular to the geometric cross-section of the component. Based on the direction of the application of the load, an axial load can be tensile or compressive. The analysis of bodies under the action of axial loads is generally studied under the branch of mechanics, known as statics.

Question

**Problem 2:** A concentrated load \( P = 36 \, \text{kN} \) is applied to the upper end of a pipe. The outside diameter of the pipe is \( D = 220 \, \text{mm} \), and the inside diameter is \( d = 200 \, \text{mm} \). Determine the vertical shear stress on the \( y \text{-} z \) plane of the pipe wall.

**Diagram Explanation:**

1. **3D Pipe Diagram:**
- Shows a vertical pipe with a force of 36 kN applied horizontally at the upper end.
- Coordinate system with axes labeled \( x \), \( y \), and \( z \) is included.

2. **Pipe Cross Section:**
- Illustrates a cross-sectional view of the pipe.
- Shows the inside diameter \( d = 200 \, \text{mm} \) and the outside diameter \( D = 220 \, \text{mm} \).
- The axes \( x \) and \( z \) are indicated to show orientation.

The purpose of this problem is to analyze the shear stress developed due to the applied force, focusing on the specific plane of interest.

Expert Solution

This question has been solved!

Explore an expertly crafted, step-by-step solution for a thorough understanding of key concepts.

SEE SOLUTION Check out a sample Q&A here

Step 1

VIEW

Step 2

VIEW

Step 3

VIEW

Step by step

Solved in 3 steps

SEE SOLUTION Check out a sample Q&A here

Knowledge Booster

Learn more about

Need a deep-dive on the concept behind this application? Look no further. Learn more about this topic, mechanical-engineering and related others by exploring similar questions and additional content below.

Similar questions

When there is a plane stress condition as shown in the figure, display this stress in the form of the maximum in-plane shear stress and the corresponding average vertical stress.
16 mm 16 mm A M B |--40 mm-|--40 mm-| B D Couple-moment M is applied to the beam, which has a cross-section, as shown in the Figure. if M = 458 Nm and ß =62 Determine the stresses at points A, B and D. Also determine the orientation of neutral axis measured from z-axis.
How do I calculate for sigma seam? Thank you
Consider a two-component rod fixed at the left end. The first component (on the left, positioned from z=0 to z=L/2) is a solid rod with a shear modulus of G and radius c1. The second component (on the right, positioned from z=L/2 to z=L) is a hollow pipe fixed to component 1 at z=L/2 with the same shear modulus and outer radius c1, but with an inner radius of c2. A torque of 6To is applied at z=L/2, and a torque of -2To is applied at z=L. What value of c2 is required to make the maximum shear stress equivalent in each component? What is the angle of twist at the free end at z=L?
The cross-sectional area of the prismatic bar is 0.02 m². If the normal and shear stresses on the plane P are d = 1.25 MPa and Te = -1.5 MPa, what are the angle and the axial force P. Figure 1
For the assembly shown in the figure helow, Determine the state of stress at point A on the cross section of the pipe at section a-a. 20 mm P= 250 a= 240 b= 140 d= 25 Soction a-a
Two solid circular shafts (i.e., AB and BC) are fixed to rigid walls at point A and C, respectively. Members AB and BC are coupled together through a rigid plate at B. As shown in the figure, an external torque is applied at point B. Determine the absolute maximum shear stress developed in the whole structure AC. Both members AB and BC are made of the aluminum alloy with shear modulus G = 60 GPa. 150 mm 100 mm B 10 mm 5 kN-m Note: ignore the effect of stress concentration. 20 mm
The simply supported beam shown supports a uniformly distributed load of w = 50 kN/m. Assume x = 1.6 m, a = 3.5 m, b = 6.0 m, xk = 2.5 m. The cross-sectional dimensions of the beam are b₁ = 305 mm, t₁ = 23 mm, d = 480 mm, tw = 14 mm, and y = 85 mm. Determine the principal stresses and the maximum shear stress acting at point H. On a piece of paper, show these stresses on an appropriate sketch. ΧΗ พ bf H H B K Ун XK Ук b K a tw d
Question 2 Derive the following formula for the distance e from the centreline of the wall to the (2 1) shear center S for the hat section of constant thickness shown in Figure Q2 3bh2 (b+2a)-8ba3 e = h2(h+6b+6a)+4a2(2a+3h) 0) Check the formula for the special case of channel section (a (2 2) 3 12 C e b Figure Q2 Hat-section wall ro N.
The stresses shown act at a point in a stressed body. The stress magnitudes are Sx = 50 MPa and Sy = 250 MPa, acting in the directions indicated in the figure. Using the equilibrium equation approach, determine the normal and shear stresses at this point on the inclined plane shown. Assume β = 46°.
For the beam shown in the figure: Determine the normal and shear stress at a point located at 4.5 ft from support B and 4 inches from the top of the section. Draw the Mohr's circle for the stresses at that point and calculate the principal stresses and the max in plane shear stress as well as their directions. Show these stresses on appropriately oriented elements. A 1600 lb 1.5 ft 80 lb/ft -9 ft B 1.5 in. 4 in 11.5 in.
3. Answer Set A only