Figure 3 shows the diver jumping action on the wooden diving board. The diver weighs 620 N and while holding himself rigid, strikes the end of wooden diving board (h=0) with a downward velocity of 1.4 m/s. The board has a thickness of 25 mm and width of 350 mm. Determine the static displacement of diving board. Q2(b) If yield strength oy = 55 MPa, based on the conservation energy of diving board, propose the suitable downward velocity that enable to initially promote the failure of wooden diving board (amax > Oy). Discuss the effect on the conservation energy and maximum stress due to uniaxial and bending loading if one support spring is added at point 0. Given : Ew = 12.6 GPa k1.65 m의 -1.2 m- 3.3 m Figure 3

Figure 3 shows the diver jumping action on the wooden diving board. The diver weighs 620 N and while holding himself rigid, strikes the end of wooden diving board (h=0) with a downward velocity of 1.4 m/s. The board has a thickness of 25 mm and width of 350 mm. Determine the static displacement of diving board. Q2(b) If yield strength oy = 55 MPa, based on the conservation energy of diving board, propose the suitable downward velocity that enable to initially promote the failure of wooden diving board (amax > Oy). Discuss the effect on the conservation energy and maximum stress due to uniaxial and bending loading if one support spring is added at point 0. Given : Ew = 12.6 GPa k1.65 m의 -1.2 m- 3.3 m Figure 3

Elements Of Electromagnetics

7th Edition

ISBN:9780190698614

Author:Sadiku, Matthew N. O.

Publisher:Sadiku, Matthew N. O.

ChapterMA: Math Assessment

Section: Chapter Questions

Problem 1.1MA

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