Plot the shear force and bending moment digrams for an 8m long beam simply supported at...

Q3: Bending moment and shear force diagrams were plotted for a cantilever beam of span 10...

Q3: Bending moment and shear force diagrams were plotted for a cantilever beam of span 10 m when subjected to a uniformly distributed load of magnitude ‘w’ kN/m over the entire span, two concentrated loads ‘2w’ kN at a distance 3 m from the free end and ‘3.5w’ kN at a distance 4.5 m from the free end respectively. It was observed that the value for maximum bending moment acting on the beam is equal to (-175 kNm). Suggest a...

Calculate the bending capacity of a simply supported concrete beam. Beam is 6m long and supporting...

Calculate the bending capacity of a simply supported concrete beam. Beam is 6m long and supporting dead load of 20KN/m and live load of 10KN/m. Compressive strength of the concrete is 25MPa and yield strength of rebars is 500MPa. Concrete beam is 300mm height 200mm width.

The slope of the bending-moment diagram is equal to the _______ of the shear-force diagram at...

The slope of the bending-moment diagram is equal to the _______ of the shear-force diagram at that point. Question 1 options: length slope area value Question 2 (2 points) Bending moments are maximum or minimum _______. Question 2 options: where the maximum distributed load is applied at the largest concentrated moment where the shear force diagram is zero where the shear force diagram reaches a maximum Question 3 (2 points) Assuming no external moments are applied to the beam, the...

A simply supported beam of 6m length carries a dead load of 10 kn/m and live...

A simply supported beam of 6m length carries a dead load of 10 kn/m and live load of 8 kn/m. It also support a point dead load of 60Kn at the centre. Using the formula calculate the moment modification factor.

overhanging beam is simply supported at san of 13m and carries of point load of 4000N...

overhanging beam is simply supported at san of 13m and carries of point load of 4000N 3m from right support the left overhangs is 3 m away from left support and has a point load of 5000N. the right overhang is of 4m carrying UDL of 200N per meter for entire rightover . draw shear force and bending moment diagram . calculate the maximum bending moment.

A simply supported beam is 3 m long. It carries a uniformly distributed load of 6...

A simply supported beam is 3 m long. It carries a uniformly distributed load of 6 kN/m throughout its span and a concentrated load of 15 kN at a point 2 m from the left support. Assuming that the beam has a rectangular shape whose width and depth are 150 mm and 250 mm, respectively. Determine the maximum flexural stress in MPa developed in the beam.

. A simply supported beam has a width of 200mm and depth of 400mm is 4m...

. A simply supported beam has a width of 200mm and depth of 400mm is 4m long. It carries a uniformly distributed load of 20 kN/m over the whole beam and a point load of 40 kN at the center of the beam. Compute the maximum deflection if the maximum slope produced in the beam is 2× ??-3 radian.

2. A simply supported beam has a width of 200mm and depth of 400mm is 4m...

2. A simply supported beam has a width of 200mm and depth of 400mm is 4m long. It carries a uniformly distributed load of 20 kN/m over the whole beam and a point load of 40 kN at the center of the beam. Compute the maximum deflection if the maximum slope produced in the beam is 2× ??-3 radian.

A simply supported composite beam (L = 4.5 m) is subjected to a positive bending moment...

A simply supported composite beam (L = 4.5 m) is subjected to a positive bending moment (680 N- m) at both ends. The beam is made of two materials in a square cross-section. Material 1 is 50x50 mm and is surrounded by a 25 mm shell of material 2. Solve for the maximum stress in each material. E1 = 100 GPa, E2 = 200 GPa.

A simply supported composite beam (L = 4.5 m) is subjected to a positive bending moment...

A simply supported composite beam (L = 4.5 m) is subjected to a positive bending moment (680 N-m) at both ends. The beam is made of two materials in a square cross-section. Material 1 is 50x50 mm and is surrounded by a 25 mm shell of material 2. Solve for the maximum stress in each material. E1 = 100 GPa, E2 = 200 GPa.