QUESTION 3Vibration absorber (also called tuned mass damper) is used to reduce* the vibration at the natural frequency of the original system. Consider a M-K system shown below.Original Systemx(t)Modified Systemx₁(1)X2(t)KKMAM0000MF(1)F(t)absorberKThis system has a natural frequency atrad. The absorber mass and the spring are attached to the original system as shown in the figure, and the values are selected so that (1) the amplitude of the original mass, M. atthe original natural frequency is zero, and (2) the new natural frequencies are moved away from the original natural frequency. The selection of absorber mass and stiffness, m and k, is easy. They have the same ratio as the ratioof the original system. That is, M/m = Klk.Find the transfer functions X1(s)/F(s) and X2(s)/F(s) before you can answer questions.What is the fundamental frequency (first natural frequency) of the modified system in rad/s? Use scientific notation with 3 signifincant figures. Omit units.Let M = 17 kg, K = 372 N/m, M/m = K/k = 3.

Step 1: Step 2: Step 3: Step 4:

Answered: QUESTION 3 Vibration absorber (also…

Elements Of Electromagnetics

7th Edition

ISBN:9780190698614

Author:Sadiku, Matthew N. O.

Publisher:Sadiku, Matthew N. O.

ChapterMA: Math Assessment

Section: Chapter Questions

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QUESTION 15 A mass-spring damper system has the following parameters: • mass 250g damping constant 1/36000 Nh/m spring stiffness 500 N/m Calculate the damped frequency. O 1. Not possible to calculate. O 2.44.7 rad/s O 3.55.2 rad/s O 4.79.4 rad/s O 5. 25.8 rad/s
please answer ans explain
By what factor does the amplitude change in one period of these damped oscillations?
2.- Determine if the system shown (modulator) is: (1 point) 2.1- Linear 2.2. Invariant in time.
part C and D
A pump of mass 30 kg is supported on a support structure which has 4 springsarranged in parallel with stiffness values of 10 kN/m, 15 kN/m, 8 kN/m and12 kN/m respectively. Viscous damping is present within the system and 1 kNs/mis applied by a damper.i) Produce a neat sketch of the system and state its equation of motion.ii) Determine the damping ratio for the system, commenting on its value. iii) Determine the damped frequency of vibration.iv) Determine the logarithmic decrement for the vibrating system.
n1=969
please be specific and explain will up vote if correct
: An undamped oscillator has a natural frequency of a rad/s. Damping is added to the system to give a damping factor equal to 0.30 s¬1. Find the corresponding Q – value and frequency of damped oscillations. 3 For a Damped Simple Harmonic Oscillator, wo? – w² = 10-w,?, where (w) is the frequency of DHO. Find Q, and the logarithmic decrement (A) of the system. If wo = 106 rad/s, Q, = 5 × 10² and m = 10-10kg, calculate the stiffness, and resistive constant (b) of the system. S For a driven damped oscillator, show that the energy dissipated per cycle by a frictional force F4 = bv : ngular frequency (w) is given by: E = nbwA². 1
A mass-spring damper system has the following parameters: • mass 250g damping constant 1/36000 Nh/m • spring stiffness 500 N/m Calculate the damped frequency. O 1.55.2 rad/s O 2.25.8 rad/s O 3. Not possible to calculate. O 4.79.4 rad/s O 5.44.7 rad/s
QI: A portion of an automobile suspension system consists of an elastic spring and a viscous damper, as shown. If the natural frequency is 10 rad/sec, a) Determine the damping ratio so that any oscillations that occur will decay from 11-0.5 m to x2-D 0.025 m. b) If the system is displaced 0.2 m from its equilibrium position, and released from rest, determine the position of the mass after it has ascillated through 3 cycles.
For the spring: k = 0.2[60] N/m. From the motor: amplitude of force = [100] N, forcing frequency = [16] rad/s. For the viscous damping: c = [20] N. s/m. If the mass is 100 kilograms, determine: 19. The amplitude of steady-state vibration in meters, 20. The phase difference in degrees. m C F = Fo cos wt

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