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The moment curvature equation is shown for the beam in the figure. What equation best describes...
The moment curvature equation is shown for the beam in the figure. What equation best describes the slope of the member at any point along its length? B А Mo L dạy ΕΙ dx² = M(x)=-M Mo A) dv dx (-2x+L) 2EI dv M. -(-x? +L) B) dx EI dv M. -(-x+ L) C ) dx ΕΙ D) dy dx M. (-x+31° x -21) 6EI
D Question 1 The moment curvature equation is shown for the beam in the figure. What equation best describes the slope of the member at any point along its length? А M dạy EI dx² M(x)=-M, A) dv dr 2EI M (-2x+1) dv_ M.(-x+1) B) dx do M dhe (-x+1) MacBook Air 80 F3 DOO OOO F4 # 3 $ A 4 % 5 ON & 7 8 9 ET- = M(x)=-M, dir? A) dv_M (-2x+L) dr 2EI dy M...
A simply supported beam AB is subjected to a triangle loading (see figure). The moment curvature equation is shown (from the left). The (El=constant) 1. Determine the deflection at middle beam. 2. Determine the rotation at middle beam. 2 kN/m A B 4 m d2v x3 ΕΙ = dx? 12 -x2+1
A cantilever beam is shown in the figure below. Using the second-order integration method (moment-curvature equation): (a) Determine the equation of the deflection curve v(x) and draw the curve (6) Determine the deflection ve and the slope OB at B. Consider Young's Modulus E = 210x10° Pa. 2N А 200 mm B > 10 m 100 mm
A cantilever beam AB is subjected to a triangle loading with concentrated moment (see figure). The moment curvature equation is shown (from the left). (El=constant) 1. Determine the deflection at point A. 2. Determine the rotation at point A. 3 kN/m 15 kN-m A B 6 m d2v ΕΙ 5x3 3 x2 – 15 2 dx2 6
Acantilever beam AB is subjected to a triangle loading with concentrated moment (see figure). The moment curvature equation is shown (from the left). (El=constant) 1. Determine the deflection at point A. 2. Determine the rotation at point A. 3 kN/m 15 kN-m B 6 m d2v EI dx- 5x3 3 --x2 - 15 6 2
structure B.Establish the equation for deflection: Use the double integration method for the uniformly loaded beam in Figure, to answer the following El is constant Ede w +G;*+ + x + 2 dy 9 dy ΕΙ dy WE w 12 + x + 2 21 + du ET dy 1 w 12 w 24 + G* + +G* + C7 wl. 2 w! 2 A. Establish the equation for slope: C. Evaluate the deflection at midspan of the beam: 3131...
A simply supported beam AB is subjected to a triangle loading (see figure). The moment curvature equation is shown (from the left). The (El=constant) 1. Determine the deflection at middle beam. 2. Determine the rotation at middle beam. 2 kN/m A B 4 m 8 d2v EI dx2 x3 12 *+z*
A simply supported beam AB is subjected to a triangle loading (see figure). The moment curvature equation is shown (from the left). The (El-constant) 1. Determine the deflection at middle beam. 2. Determine the rotation at middle beam. 2 kN/m B 4 m 8 EI 12 MacBook Air DOO 008 A tA % A - 5 & 7 6 I 0 * 8 9 R T
A simply supported beam AB is subjected to a triangle loading (see figure). The moment curvature equation is shown (from the left). The (El-constant) 1. Determine the deflection at middle beam. 2. Determine the rotation at middle beam. 2 kN/m A B 4.m x3 EI dx2 = - 2 COM MacBook Air 20 COD F4 FS F6 ►II # $ دیا 4 % 5 6 & 7 8 9