Part 2 * Your answer is incorrect. The z-component of momemt M will cause compression at A and B, and tension at C and D. The y-component of moment M will cause compression at A and D, and tension at B and C. The maximum tensile bending stress will occur at point C. Calculate the magnitude of the largest bending moment that can be applied so that the stress at corner C does not exceed 205 MPa. Answer: M = 1 -3.59E1 eTextbook and Media Save for Later Part 3 * Your answer is incorrect. Answer: The z-component of moment M will cause compression at A and B, and tension at C and D. The y-component of moment M will cause compression at A and D, and tension at B and C. The maximum compressive bending stress will occur at point A. Calculate the magnitude of the largest bending moment that can be applied so that the stress at corner A does not exceed 205 MPa. M = i eTextbook and Media Save for Later 10 7.98E1 Part 4 * Your answer is incorrect. Answer: kN-m Determine the maximum bending moment that can be applied to this cross section. M=1 8.31E1 kN-m kN-m Submit Answer Attempts: 1 of 5 used Submit Answer

Structural Analysis
6th Edition
ISBN:9781337630931
Author:KASSIMALI, Aslam.
Publisher:KASSIMALI, Aslam.
Chapter2: Loads On Structures
Section: Chapter Questions
Problem 1P
icon
Related questions
Question

Part 2,3,4

The moment M acting on the cross section of the tee beam is oriented at an angle of 0 = 64° as shown. Dimensions of the cross section
are b;= 245 mm, t+= 22 mm, d = 279 mm, and t= 18 mm. The allowable bending stress is 205 MPa. What is the largest bending
moment M that can be applied as shown to this cross section?
bf
M
Part 1
k
B
Your answer is correct.
y = 2.04E2
Iz = 7.41E7
ly= 2.71E7
Determine the distance in the y-direction from line DC to the centroid of the area. Then calculate the area moment of inertia
about both the z-axis and the y-axis.
Answer:
d
eTextbook and Media
mm
mm4
mm4
Attempts: 4 of 5 used
Transcribed Image Text:The moment M acting on the cross section of the tee beam is oriented at an angle of 0 = 64° as shown. Dimensions of the cross section are b;= 245 mm, t+= 22 mm, d = 279 mm, and t= 18 mm. The allowable bending stress is 205 MPa. What is the largest bending moment M that can be applied as shown to this cross section? bf M Part 1 k B Your answer is correct. y = 2.04E2 Iz = 7.41E7 ly= 2.71E7 Determine the distance in the y-direction from line DC to the centroid of the area. Then calculate the area moment of inertia about both the z-axis and the y-axis. Answer: d eTextbook and Media mm mm4 mm4 Attempts: 4 of 5 used
Part 2
* Your answer is incorrect.
The z-component of momemt M will cause compression at A and B, and tension at C and D. The y-component of moment M will
cause compression at A and D, and tension at B and C. The maximum tensile bending stress will occur at point C. Calculate the
magnitude of the largest bending moment that can be applied so that the stress at corner C does not exceed 205 MPa.
Answer:
M = 1 -3.59E1
eTextbook and Media
Save for Later
Part 3
* Your answer is incorrect.
Answer:
The z-component of moment M will cause compression at A and B, and tension at C and D. The y-component of moment M will
cause compression at A and D, and tension at B and C. The maximum compressive bending stress will occur at point A. Calculate
the magnitude of the largest bending moment that can be applied so that the stress at corner A does not exceed 205 MPa.
M = i
eTextbook and Media
Save for Later
10
7.98E1
Part 4
* Your answer is incorrect.
Answer:
kN-m
Determine the maximum bending moment that can be applied to this cross section.
M=1 8.31E1
kN-m
kN-m
Submit Answer
Attempts: 1 of 5 used
Submit Answer
Transcribed Image Text:Part 2 * Your answer is incorrect. The z-component of momemt M will cause compression at A and B, and tension at C and D. The y-component of moment M will cause compression at A and D, and tension at B and C. The maximum tensile bending stress will occur at point C. Calculate the magnitude of the largest bending moment that can be applied so that the stress at corner C does not exceed 205 MPa. Answer: M = 1 -3.59E1 eTextbook and Media Save for Later Part 3 * Your answer is incorrect. Answer: The z-component of moment M will cause compression at A and B, and tension at C and D. The y-component of moment M will cause compression at A and D, and tension at B and C. The maximum compressive bending stress will occur at point A. Calculate the magnitude of the largest bending moment that can be applied so that the stress at corner A does not exceed 205 MPa. M = i eTextbook and Media Save for Later 10 7.98E1 Part 4 * Your answer is incorrect. Answer: kN-m Determine the maximum bending moment that can be applied to this cross section. M=1 8.31E1 kN-m kN-m Submit Answer Attempts: 1 of 5 used Submit Answer
Expert Solution
trending now

Trending now

This is a popular solution!

steps

Step by step

Solved in 4 steps with 3 images

Blurred answer
Knowledge Booster
Light gauge steel frame structures
Learn more about
Need a deep-dive on the concept behind this application? Look no further. Learn more about this topic, civil-engineering and related others by exploring similar questions and additional content below.
Recommended textbooks for you
Structural Analysis
Structural Analysis
Civil Engineering
ISBN:
9781337630931
Author:
KASSIMALI, Aslam.
Publisher:
Cengage,
Structural Analysis (10th Edition)
Structural Analysis (10th Edition)
Civil Engineering
ISBN:
9780134610672
Author:
Russell C. Hibbeler
Publisher:
PEARSON
Principles of Foundation Engineering (MindTap Cou…
Principles of Foundation Engineering (MindTap Cou…
Civil Engineering
ISBN:
9781337705028
Author:
Braja M. Das, Nagaratnam Sivakugan
Publisher:
Cengage Learning
Fundamentals of Structural Analysis
Fundamentals of Structural Analysis
Civil Engineering
ISBN:
9780073398006
Author:
Kenneth M. Leet Emeritus, Chia-Ming Uang, Joel Lanning
Publisher:
McGraw-Hill Education
Sustainable Energy
Sustainable Energy
Civil Engineering
ISBN:
9781337551663
Author:
DUNLAP, Richard A.
Publisher:
Cengage,
Traffic and Highway Engineering
Traffic and Highway Engineering
Civil Engineering
ISBN:
9781305156241
Author:
Garber, Nicholas J.
Publisher:
Cengage Learning