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please show all work A cross-section is subjected to a maximum shear of V=220 kN (see...
A cross-section is subjected to a maximum shear of V=220 kN (see figure): 1. Determine the centroid of the cross-section. 2. Calculate the moment of inertia (1) of the cross-section. 3. Determine the shear stress at point A in the cross-section. -250 H10 06 -100 10 A. 300 -100 -10 08 10 125 10 All dimensions are in millimeters
A cross-section is subjected to a maximum shear of V=220 kN (see figure): 1. Determine the centroid of the cross-section. 2. Calculate the moment of inertia (1) of the cross-section. 3. Determine the shear stress at point A in the cross-section. -250 OILA 90 100 D 10 300 -100 10 80 10 125 10 All dimensions are in millimeters MacBook Air ** F2 SO DOO DOO FS # $ 07
A cross-section is subjected to a maximum shear of V=160 kN (see figure): 1. Determine the centroid of the cross-section. 2. Calculate the moment of inertia (1) of the cross-section. 3. Determine the shear stress at point A in the cross-section. 715 -250 100 -145 AL -10 -300 145 10 125 -10 200 All dimensions are in millimeters
A cross-section is subjected to a maximum shear of V=160 kN (see figure): 1. Determine the centroid of the cross-section. 2. Calculate the moment of inertia (l) of the cross-section. 3. Determine the shear stress at point A in the cross-section. -250 715 -100 -145 AL -10 -300 -145 10 125 10 -200 All dimensions are in millimeters
The internal shear force at a certain section of a steel beam is V=185 kN. The beam cross section shown in the figure has dimensions of tf=17 mm, bf=300 mm, d=394 mm, and tw=10 mm. Determine: (a) the shear stress at point A, which is located at yA=71 mm below the centroid of the wide-flange shape. (b) the maximum horizontal shear stress in the wide-flange shape. The internal shear force at a certain section of a steel beam is V=...
With a U cross section, is subjected to uniformly distributed force 11 kN/m and a concentrated load of 12 kN as shown. (a) the reaction at supports A and B, (b) sketch the shear diagram and the moment diagram, (c) determine the location of neutral axis of the cross section and calculate its area moment of inertia about the neutral axis, and (d) determine absolute maximum bending stress and (e) absolute maximum transverse shear stress.
(a) If the wide-flange beam shown in Figure Q4a is subjected to a shear of V = 23 kN i. Calculate the moment of inertia of the cross section about the neutral axis.ii. Determine the shear stress on the web at A.(b) The state of stress at a point is shown on the element in Figure Q4b. Determine graphically using Mohr's circle i. The principal stresses. ii. The orientation of the principal planes.iii. The maximum in-plane shear stress and average normal stress at...
The simply supported beam, with a U cross section, is subjected to a uniformly distributed force of 8 kN/m and a concentrated load of 12 kN as shown. (a) Determine the reaction at supports A and B, (b) sketch the shear diagram and the moment diagram, (c) determine the location of the neutral axis of the cross section and calculate its area moment of inertia about the neutral axis, and (d) determine absolute maximum bending stress and (e) absolute maximum...
1. A beam has a max moment of 45 kN-m. The cross section of the beam is shown in the figure below. a. State the distance of the centroid from the 2 axis. b. Calculate the area moment of inertia about the centroid. c. Calculate the maximum stress in the beam 300 mm 20 mm 185 mm 20 mm 35 mm 1. A beam has a max moment of 45 kN-m. The cross section of the beam is shown in...
A beam is loaded by a shear force V. The beam cross-section is shown below. The moment of inertia of the cross-section is 347.1 in4. The centroid of the cross-section is 6.25 inches from the base. Determine: a) the shear stress at point A. b) the shear stress at point B. c) the maximum shear stress in the cross-section. V = 50 (kips) The maximum shear stress at point A is _____(ksi) The maximum shear stress at point B is...