5-10. The cable is subjected to a uniform loading of w = 250 lb/ft. Determine the maximum and minimum tension in the cable. 5-13. The trusses are pin connected and suspended from the parabolic cable. Determine the maximum force in the cable when the structure is subjected to the loading shown. 60 ft 15 ft 14 16 ft i G H B sk @ 12 f = 48 ft e 12 ft = 48 ft- Proh. 5-10 5-11. The cable is subjected to a uniform loading of w = 250 lb/ft. Determine the maximum and minimum tension in the cable. Proh. S-13 5-14. Determine the maximum and minimum tension in the parabolic cable and the force in cach of the hangers. The girde is subjected to the uniform load and is pin connected at B. 5-15. Draw the shear and moment diagrams for the pir connected girders AB and BC.The ca has a parabolic shape Prob. 5-11

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5-10. The cable is subjected to a uniform loading of w = 250lb/ft. Determine the maximum and minimum tension in the cable. 5-13. The trusses are pin connected and suspended from the parabolic cable. Determine the maximum force in the cable when the structure is subjected to the loading shown. 60 ft 15 ft 14 ft 6 ft 16 ft G H B Prob. 5-10 5k 4 k -4 @ 12 ft = 48 ft 4@ 12 ft = 48 ft- 5-11. The cable is subjected to a uniform loading of Prob. 5-13 w = 250 lb/ft. Determine the maximum and minimum tension in the cable. 50 ft 6 ft 5-14. Determine the maximum and minimum tension in the parabolic cable and the force in cach of the hangers The girder is subjected to the uniform load and is pin connected at B. 5-15. Draw the shear and moment diagrams for the pin connected girders AB and BC.The cable has a parabolic shape. Prob. 5-11 *5-12. The cable will break when the maximum tension reaches Tmax = 12 kN. Determine the uniform distributed load w required to develop this maximum tension. IT 9 ft 15 m 1 ft 6 m 10 ft 2k/ft 10 ft 30 ft Prob. 5-12 Probs. 5–14/15