Lab 1 Instructions

A vibrating system with mass 3 kg, stiffness 21 N-s/m and damper having damping coefficient 10 N-s/m When an exciting force of magnitude 27 sin2t is acting, what would be the time period of oscillations?

It is observed from the magnitude plot of a  compliance transfer function of a mass spring damper that the value at a very small frequency 0.0001 is 3.71 meters and at resonance 1.10 rad/s is 7.10 meters. What is the natural frequency, damping coefficient, stiffness, and mass of the system?

machine dynamics A car with a mass of 1503 kg, a spring constant of 307027 N/m of suspension springs, a damping degree of shock absorbers of 0.5, an amplitude of 5 cm, and a wavelength of 4 m, while driving on a bumpy sinusoidal road;a) The vibration amplitude of the car in the resonant wn=w state.b) At what speed will the car resonate?c) Find the regular regime vibration amplitude when the car is traveling at 80 km/h.

Mechanical Vibrations Question is image A 300-kg machine is attached to an elastic foundation of stiffness 3.1 x E6 N/m and damping ratio 0.06. When excited by a frequency squared excitation at very large speeds, the machine's steady-state amplitude is 10 mm. What is the maximum steady-state amplitude the machine would experience at lower speeds?

MECHANICAL VIBRATIONS    An unknown mass m is attached to the end of a linear spring with unknown stiffness coefficient k. The system has natural frequency of 30 rad/s. When a 0.5 kg mass is added to the unknown mass m, the natural frequency is lowered to 20 rad/s. Determine the mass m and the stiffness coefficient k.

A spring mass system with a natural frequency fn = 20 Hz is attached to a vibration table. Thetable is set to vibrate at 16 Hz, with a maximum acceleration 0.25 g. Answer the followingquestions. Justify your answers d. What is the maximum acceleration of the mass assuming the packaging can be modeled asa viscous damper with a damping ratio of 0.2?e. Is the motion of the mass in phase or out of phase with the motion of the table?

Please show all work. will upvote, thanks An input force f = F‧sin(ωt) is applied to the body in both systems along the direction x. -Which of the two systems performs better in the frequency domain in terms of reducing the steady-state displacement amplitude X of the body ? Known are: m = 1kg, c = 5 Ns/m and k = 100 N/m?

A weight of 10lb is suspended by a spring having a modulus of 15 lb-s/in. When displaced and permitted to oscillate freely, it is found that the amplitude diminished from 1.5 in to 1.316 in in exactly 10 cycles. a.) determine the system mathematical model, b.) time period of the system, c.) system percent overshoot

A suspension system of Volvo articulated dump truck is to be modelled mathematically given the following data: keq = 10.5 MN/m, m = 30 tons, and c = 300 N-s/m. If the harmonic forcing function is 2000 cos 5t N with the initial displacement and velocity to be 0 and 30 m/s respectively, determine the steady state and total response of the system.

2.A 31 kg skip attached to a steel rope on a crane is used to hoist bricks from the ground to the top of a construction site. The steel rope is wound onto a lifting drum with a diameter of 700 mm and rotational frequency of 52 revolutions per minute. The lifting drum is situated on the top floor which is 196 m high. How many seconds will it take to lift bricks, three quarters up the height of the building?

Find the maximum velocity of a free vibration with a response of 4(d^2 x/dt^2) + 25x = 0. Initial displacement of 0 and velocity of 1 m/s.

Determine the steady state time response x(t) of a viscously damped system subjected to harmonic base excitation for the following data : m = 15 kg, c = 25 N.s/m, k = 300 N/m, y(t) = 0.04 sin ( 5t ) m. %3D

The block diagram given below; A) Reduce it B) G1(s)=2/s ; G2(s)=1/4s+2 ; G3(s)=4 ;H(s)=0.5   Given the values of the system; find the time constant, its natural frequency and damping rate and explain what kind of dynamic behavior it exhibits accordingly. C)Find the poles and zeros of the system according to the values in (B).Is the system stable? Find the unit step response (Inverse Laplace).

A block of mass m = 16 kg oscillates attached to a spring of spring constant K = 162 N/m. The motion of the block is also acted upon by a damping force proportional to the velocity of the form Fd = -bv, where b = 36√ 2 kg/s. The system is excited by a sinusoidal force of maximum value F0 = 7 N. If the excitation frequency varies, at what frequency ω (in rad/s) will resonance occur? Choose the closest value. a) 63/4 rad/s b) 9/28 rad/s c) 567/4 rad/s d) 9/4 rad/s

A two degree of freedom damped system has natural frequencies 2 rad/s and 3 rad/s and corresponding mode shapes {21}{ 2 1 } and {1−1}{ 1 − 1 } . A damping ratio of 2% is assumed for both modes.  The initial displacement is {10}{ 1 0 }mm and initial velocity is {21}{ 2 1 }mm/s. The displacement of the first degree of freedom in mm at time t=3 s is

A certain mass is driven by base excitation through a spring (Figure P4.13). Its parameter values are m = 100 kg, c = 1000 N * s/m, and k = 10,000 N/m. Determine its peak frequency w_p, it’s peak M_p, and its bandwidth.

In this Problem, the system of Fig. 5.4.14 (Attached) is taken as a model for an undamped car with the given parameters in fps units. (a) Find the two natural frequencies of oscillation (in hertz). (b) Assume that this car is driven along a sinusoidal washboard surface with a wavelength of 40 ft. Find thetwo critical speeds. m = 100, I =1000, L1 =6, L2 = 4, k1 = k2 = 2000

A particular naturally vibrating system is subject to damping. The system consists of a small mass m = 0.1 kg, the system stiffness k = 200 Nm-1 and the damping coefficient c = 0.25 kgs-1 . Determine the values of the natural and damped frequencies, the damping factor, damping ratio, periodic time and logarithmic decrement. Sketch and describe the nature of the motion

If a mass of 6 kg oscillates on a spring having a mass 3 kg and stiffness 11200 N/m, then the natural frequency of the system in rad/sec will be

A 1.5-kg mass attached to an ideal massless spring with a spring constant of 20.0 N/m oscillates on a horizontal, frictionless track. At time t = 0.00 s, the mass is released from x = 0.0 cm with a velocity of 0.370 m/s to the left. Find the followingA. Time periodB. Total mechanical energy of the massC. AmplitudeD. Phase constant of motion. Discuss the two possible values of phase constant you get and explain how you arrived at the correct answer. Write the equation of motion.E. Maximum acceleration of the mass. (Acceleration is maximum when it ispositive). How long after the release does the maximum acceleration occur?F. Draw the position-time graph for one cycle of motion.

Vibrations Question The governing equation of motion of a single degree–of–freedom (SDOF) system is given by 5xdoubledot(t)+20xdot(t)+1800x(t)=10cos(15t)+30sin(5t)(assume the units are Newtons) and the initial conditions of the system are given asx(0)=0.02m and v(0)=0.95m/sAnalytically obtain the total response of the system

A 35 kg electric motor that operates at 40 + 10u Hz is mounted on an elastic foundation of stiffness 3× 106 N/m. The phase difference between the excitation and the steady state response is 21°. What is the damping ratio of the system?

Don't give incorrect solution..A structure is modeled as a damped oscillator having a spring constant k = 30 kip/in and undamped natural frequency = 25 rad/sec. Experimentally it was found that a force of 1 kip produced a relative velocity of 1.0 in/sec in the damping element. Determine: a) The damping ratio §. b) The damped period TD.