20 points Question 13 . For steeluse 207 GPA ands - 7875 kg/m Compute the second...
2. A steel beam has a rectangular cross section (b mm and h mm) with a length, L m. For steel, E in GPA and pin kg/m3. The beam supported in two different ways: (i) Free-Free ii) Fixed-Free (iii) Fixed-Fixed (iv) Pinned-Pinned (a) Free-hand sketch the beams and list boundary conditions for each. (b) Compute the three lowest temporal frequencies for each beam. (c) Free-hand sketch the first three mode shapes for each beam. Use the following Table for specifications:...
2. A steel beam has a rectangular cross section (b mm and h mm) with a length, L m. For steel, E in GPA andp in kg/m The beam supported in: Fixed-Free a) List the boundary conditions b Compute the three lowest temporal frequencies E (GPa) Density, p(kg/m2) Lenth,L (m) b(m) h(m) 1.50 0.155 0.060 200 7750 2. A steel beam has a rectangular cross section (b mm and h mm) with a length, L m. For steel, E in...
2. A steel beam has a rectangular cross section (b mm and h mm) with a length, L m. For steel, E in GPA andp in kg/m The beam supported in: Fixed-Free a) List the boundary conditions b) Compute the three lowest temporal frequencies E (GPa) Density, p(kg/m3) Lenth, L (m) b(m) h(m) 1.50 0.155 0.060 200 7750 2. A steel beam has a rectangular cross section (b mm and h mm) with a length, L m. For steel, E...
A steel beam has a rectangular 2. cross section (b mm and h mm) with a length, L m. For steel, E in GPA and p in kg/m3 The beam supported in: Fixed-Free a) List the boundary conditions b) Compute the three lowest temporal frequencies. Lenth, L (m) b (m) h(m) E (GPa) Density, p (kg/m3) 1.50 0.155 0.060 200 7750 A steel beam has a rectangular 2. cross section (b mm and h mm) with a length, L m....
uestion 1 points ILO, Marks) - A steel beam has a rectangular cross section ( - 160 mm and h65 mm) with a length -2.25 m. For steel - 207 GPA and p7875 km. Using the table of common condition for beams, calculate and match the fundamental frequency of ration for the beam under the stated boundary conditions. 1. Beam is simply supported on both ends answer is Beam is cantilevered on both ends answer is radas Beam catevered on...
A beam with length L-2 m and rectangular cross-section of width b-75 mm and height h 150 mm has a uniformly distributed load of intensity q 2.5 kN/m (see figure below). What is the maximum deflection δmax in millimeters? The material is aluminum with modulus of elasticity E 70 GPa. T77
C5.2 The cantilever beam of length L has a rectangular cross section of constant width b. The height h of the beam varies as(h2 - h)(x/L)2. The magnitude of the uniformly distributed load is wo. Given L, b, hi, h2, and wo, construct an al gorithm to plot the maximum normal stress acting on the cross section as a function of x. (a) Run the algorithm with L 2 m, b 25 mm, h 30 mm, h2120 mm, and wo...
2. Consider a cantilevered beam with length L = 3 m, uniform E = 180 GPa, Iz- 5.375 × 10-8 m. and ρ 3.0 kg/m. (a) (20 points) Compute, by hand, the first 5 (lowest) natural frequencies for this beam. Note, unlike for the simply-supported beam problem, you will not be able to solve, analytically, the transcendental equation obtained from the application of the boundary conditions to the general free vibration solution. So, use Matlab roots of this equation numerically
2. [1o pl. A steel ball of 2 kg mass is dropped from a height he 3 m at the center of a simply- supported aluminum beam (E-70 GPa) with rectangular cross section, see Fig. below. Assume an"efficiency factor", 1.0 and calculate the impact force, and defection of the beam upon mpact Om 3 bh PL BET 12, 1 2. [1o pl. A steel ball of 2 kg mass is dropped from a height he 3 m at the center...
Backboard O dynamic balancing QUESTION 27 Q20: The rotor of a steam turbine with mass 10.5 kg is mounted on steel shaft (E 207 GPa). The shaft diameter is 49 mm and is 1.8 m long. The shaft is supported at the two ends by the bearings. The turbine rotor has an eccentricity of 9.0 mm and operates at 7200 rpm (754.0 rad/s). Determine the natural frequency of the system in rad/s. Rotor In 214.279 rad/s O 50985.64 rad/s 45915.49...