For the beam and loading shown, use discontinuity functions to compute (a) the slope of the beam at C (positive if counterclockwise and negative if clockwise). (b) the deflection of the beam at C. Assume LAB = 230 mm, LBc= 170 mm, LcD= 130 mm, LDE = 290 mm, Mg = 280 N-m, P = 1260 N and a constant value of El = 510x 106 N- mm2 for the beam. MB B |C LAB LBC LcD. LDE Answers: rad (a) Oc = mm (b) Vc=

For the beam and loading shown, use discontinuity functions to compute (a) the slope of the beam at C (positive if counterclockwise and negative if clockwise). (b) the deflection of the beam at C. Assume LAB = 230 mm, LBc= 170 mm, LcD= 130 mm, LDE = 290 mm, Mg = 280 N-m, P = 1260 N and a constant value of El = 510x 106 N- mm2 for the beam. MB B |C LAB LBC LcD. LDE Answers: rad (a) Oc = mm (b) Vc=

Mechanics of Materials (MindTap Course List)

9th Edition

ISBN:9781337093347

Author:Barry J. Goodno, James M. Gere

Publisher:Barry J. Goodno, James M. Gere

Chapter9: Deflections Of Beams

Section: Chapter Questions

Problem 9.2.3P: -3 The deflection curve for a simple beam AB (see figure) is given by v=q0x360LEI(7L410L2x2+3x4)...

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-3 The deflection curve for a simple beam AB (see figure) is given by v=q0x360LEI(7L410L2x2+3x4) Describe the load acting on the beam.
For the beam and loading shown, use discontinuity functions to compute(a) the slope of the beam at C (positive if counterclockwise and negative if clockwise).(b) the deflection of the beam at C.Assume LAB = 210 mm, LBC = 140 mm, LCD = 120 mm, LDE = 260 mm, MB = 200 N-m, P = 1080 N and a constant value of EI = 590 × 106 N-mm2 for the beam.
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