Your answer is partially correct. A simply supported wood beam that is 13.5 m long carries a 39 kN concentrated load at B. The cross-sectional dimensions of the beam are b = 155 mm, d = 410 mm, a = 105 mm, and c = 50 mm. Section a-a is located at x = 2.3 m from B. (a) At section a-a, determine the magnitude of the shear stress in the beam at point H. (b) At section a-a, determine the magnitude of the shear stress in the beam at point K. (c) Determine the maximum horizontal shear stress that occurs in the beam at any location within the entire span. (d) Determine the maximum tensile bending stress that occurs in the beam at any location within the entire length. P H A B L 2L 3 3 Answer: (a) TH = i 46778 КРа (b) TK = i КРа 2629 (c) Tmax КРа i 1198 (d) Omax= MPa 26.94

Structural Analysis
6th Edition
ISBN:9781337630931
Author:KASSIMALI, Aslam.
Publisher:KASSIMALI, Aslam.
Chapter2: Loads On Structures
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Your answer is partially correct.
A simply supported wood beam that is 13.5 m long carries a 39 kN concentrated load at B. The cross-sectional dimensions of the beam
are b = 155 mm, d = 410 mm, a = 105 mm, and c = 50 mm. Section a-a is located at x = 2.3 m from B.
(a) At section a-a, determine the magnitude of the shear stress in the beam at point H.
(b) At section a-a, determine the magnitude of the shear stress in the beam at point K.
(c) Determine the maximum horizontal shear stress that occurs in the beam at any location within the entire span.
(d) Determine the maximum tensile bending stress that occurs in the beam at any location within the entire length.
P
H
A
B
K
L
2L
3
3
Answer:
(a) TH = i
46778
КРа
(b) TK = i
КРа
2629
(c) Tmax
КРа
i
1198
(d) Omax=
MPa
26.94
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Transcribed Image Text:Your answer is partially correct. A simply supported wood beam that is 13.5 m long carries a 39 kN concentrated load at B. The cross-sectional dimensions of the beam are b = 155 mm, d = 410 mm, a = 105 mm, and c = 50 mm. Section a-a is located at x = 2.3 m from B. (a) At section a-a, determine the magnitude of the shear stress in the beam at point H. (b) At section a-a, determine the magnitude of the shear stress in the beam at point K. (c) Determine the maximum horizontal shear stress that occurs in the beam at any location within the entire span. (d) Determine the maximum tensile bending stress that occurs in the beam at any location within the entire length. P H A B K L 2L 3 3 Answer: (a) TH = i 46778 КРа (b) TK = i КРа 2629 (c) Tmax КРа i 1198 (d) Omax= MPa 26.94 Save for Later Attempts: 2 of 3 used Submit Answer Using multiple attempts has impacted your score.
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