Each wire PO and PN are the same except for their lengths. MN is a rigid bar and is free to rotate about Point M. Must include free-body diagram and sketches used to obtain equations of equilibrium and compatibility. Show all work.
a. Derive formulas for the tensile force in wires PO and PN due to the concentrated force F acting at Point N.
b. Derive formulas for the elongation in wires PO and PN
Each wire PO and PN are the same except for their lengths. MN is a rigid...
Each wire PO and PN are the same except for their lengths. MN is a rigid bar and is free to rotate about Point M. Must include free-body diagram and sketches used to obtain equations of equilibrium and compatibility. Show all work to receive full credit. a M rigid bar o N pin support 2a a F a. Derive formulas for the tensile force in wires PO and PN due to the concentrated force F acting at Point N. (20...
A 3 m rigid bar AB is supported with a vertical translational spring at A and a pin at B The bar is subjected to a linearly varying distributed load with maximum intensity g Calculate the vertical deformation of the spring if the spring constant is 700 kN/m. (ans: 21.43 mm) 2. A steel cable with a nominal diameter of 25 mm is used in a construction yard to lift a bridge section weighing 38 kN. The cable has an...
Consider a cylindrical capacitor like that shown in Fig. 24.6. Let d = rb − ra be the spacing between the inner and outer conductors. (a) Let the radii of the two conductors be only slightly different, so that d << ra. Show that the result derived in Example 24.4 (Section 24.1) for the capacitance of a cylindrical capacitor then reduces to Eq. (24.2), the equation for the capacitance of a parallel-plate capacitor, with A being the surface area of...