1. Determine the equivalent mass, equivalent stifiness and natural frequency of the system in the figure...
1. Calculate the natural circular frequency on of the single mass system shown in the figure for small oscillations. The mass and friction of the pulley are negligible. Use the displacement, x, of mass m as the generalized coordinate. What is the tension in the cable during oscillation? (20%) 2k
1. Calculate the natural circular frequency on of the single mass system shown in the figure for small oscillations. The mass and friction of the pulley are negligible. Use the displacement, x, of mass m as the generalized coordinate. What is the tension in the cable during oscillation? (20%) 2k
1. Calculate the natural circular frequency on of the single mass system shown in the figure for small oscillations. The mass and friction of the pulley are negligible. Use the...
determine the equivalent mass(meq)and equivalent
spring stiffness of the system shown in the figure below using x as
the generalized coordinate
neral MES 382: Vibration & Noise Control Determine the equivalent mass (megl and equivalent spring stiffness (kea) of the syslem shown in the figure below using x as the generalized coordinate. b. ko Jo k2 k1
3) For the single degree of freedom system shown below: a) Use the equivalent system method to derive the differential equation governing the motion of the system, taking χ as the Slender har of mass m generalized coordinate. Rigid 1 link b) If m-6 kg, M = 10 kg, and k=500 N/m, determine the value of c that makes the system critically damped. c) For the values obtained in part (b), determine the response of the system, x(t) if x(0)=...
Derive the equation of motion and find the natural frequency of the system shown below (1) Cylinder, mass m k R с Pure rolling 1 Αν B I US EE Draw a free body diagram (FBD) with all the forces. Use either Newton's or Lagrange's energy method to derive the equation of motion - Calculate the natural frequency
4. The pulley in the system of Figure 4 has a centroidal mass moment of inertia / Let x be the displacement of the cart, measured to the right from the system's equilibrium position. Determine the differential equation governing the motion of the system, using x as the generalized coordinate. Figure 4
2. Consider the mass-spring system shown in the figure below. It can be shown that the motion of the mass is governed by the equation a=-sw^2, where s and a are the position and acceleration of the mass, respectively, and w is a constant (which is referred to as the natural frequency of the system). Derive the equation describing the velocity of the mass in terms of the position. Assume that the velocity of the mass is v(subzero) when s=0...
Solve a,b and c
The vibratory movement of the engineering system shown in Figure 3 can be described by two generalised coordinates, x, a Cartesian coordinate, and 6, a polar coordinate systems. The mass m and its mass moment of inertia about an axis that goes through its centre of gravity G is J. When the system is slightly pushed down from the top comer at the right hand edge of mass m, the induced vibrational motion is found to...
Q1- For the system shown below, with small mass of value (m) and lever of mass moment of inertia (J). • find equivalent mass, equivalent stiffness, and equivalent damping, all these interms of (x) displacement . Get equation of motion Interms of these equivalent quantities. • Find natural frequency (Wn) and damping ratio (zeta). • Find X(t) when the system condition is critically damping ,,X(0)=M and v(0)=0. tinfring
Full steps
3) (35 percent) Determine the differential equation of the system in the figure below using as the generalized coordinate using (a) Free-body diagram method by applying Newton's laws and (b) Equivalent systems method. 2k Slender bar of mass m Nie - -