A three hinged semi-circular arch of radius 15 m carries a uniformly distributed load of 10...

26.51 The bending moment in an arch is proportional to: Vertical ordinate of the arch Intercept...

26.51 The bending moment in an arch is proportional to: Vertical ordinate of the arch Intercept between the arch axis and the funicular polygon Vertical ordinate of the funicular polygon None of the above 26.52 A cable can resist: Axial thrust Shear force Torsion Tension 26.53 A suspended cable hinged at two ends is a: Statically unstable structure Statically indeterminate structure Geometrically unstable structure 26.54 A suspended cable stiffened by a three hinged truss is: Statically indeterminate Geometrically indeterminate Geometrically...

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 propped beam of 2m span carries a uniformly distributed load of 100kN/m spread over its...

A propped beam of 2m span carries a uniformly distributed load of 100kN/m spread over its entire length. Calculate the maximum deflection in mm. EI is constant. Use the area moment method.

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...

The beam is subjected to a uniformly distributed load w= 12 kN/m. The beam is a...

The beam is subjected to a uniformly distributed load w= 12 kN/m. The beam is a two-span continuous beam. The length of each span is L = 2 m. The beam is made of steel. Young's modulus (E) of steel is 200 GPa. The value of the moment of inertia is 21 * 106 mm4. Use the force method given in Week 6. Determine the reaction at the middle support B. Select one: a. 6.00 kN b. 18.00 kN c....

3. A cantilever beam of span 5m is subjected to a uniformly distributed load of 30...

3. A cantilever beam of span 5m is subjected to a uniformly distributed load of 30 kN/m over the whole span. If the beam is made of Iron with E = 104 N/mm2 and moment of inertia I = 108 mm4. Apply the theroems of moment area method and find out the slope at the free end and deflection at the center of the beam?

4 A rectangular footing 8 m x 12 m carries a uniformly distributed load of (900+...

4 A rectangular footing 8 m x 12 m carries a uniformly distributed load of (900+ 10Y) kN/m2. Evaluate the vertical pressure at a point (2+0.5Y) m below the foundation and having x, y coordinates as (-5,-8) with respect to the central axis of the footing.    y=2

A net charge of 0.2 pC (picocoulomb) is uniformly distributed on a circular hoop of radius...

A net charge of 0.2 pC (picocoulomb) is uniformly distributed on a circular hoop of radius y=0.3 m. a) Determine the potential and the electric field strength (E= -dV/dz) at the center of the hoop (z=0) and at a point on the axis of the hoop 0.4 m from the center. (10 points) b) Where on the axis is the field strength a maximum? (5 points) (Hint: to determine maximum of E, equate dE/dz = 0, and find the value...

A straight, nonconducting plastic wire 7.50cm long carries a charge density of 130nC/m distributed uniformly along...

A straight, nonconducting plastic wire 7.50cm long carries a charge density of 130nC/m distributed uniformly along its length. It is lying on a horizontal tabletop. Part C If the wire is now bent into a circle lying flat on the table, find the magnitude and direction of the electric field it produces at a point 5.00cm directly above its center.

A nonconducting solid sphere of radius 2.80 cm carries a uniformly distributed positive charge of 6.60×10-9...

A nonconducting solid sphere of radius 2.80 cm carries a uniformly distributed positive charge of 6.60×10-9 C. Calculate the magnitude of the electric field at a point 1.60 cm away from the center of the sphere. Calculate the magnitude of the electric field at a point 3.60 cm away from the center of the sphere. Assume that the sphere is conducting. Calculate the magnitude of the electric field at a point 1.60 cm away from the center of the sphere....