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System of Particles & Rotational Motion Practice Questions - DPP for JEE
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Page 1 1. (b) I = 1.2 kg m 2 , E r = 1500 J, a = 25 rad/sec 2 , ? 1 = 0, t = ? As E r From 50 = 0 + 25 t, ? t = 2 seconds 2. (a) F = 20t – 5t 2 ? ? ? ? (as ? = 0 at t = 0, 6s) ? ? = 36 rad ? 3. (b) Since no external torque act on gymnast, so angular momentum (L=I ) is conserved. After pulling her arms & legs, the angular velocity increases but moment of inertia of gymnast, decreases in, such a way that angular momentum remains constant. 4. (b) The M.I. about the axis of rotation is not constant as the perpendicular distance of the bead with the axis of rotation increases. Also since no external torque is acting. Page 2 1. (b) I = 1.2 kg m 2 , E r = 1500 J, a = 25 rad/sec 2 , ? 1 = 0, t = ? As E r From 50 = 0 + 25 t, ? t = 2 seconds 2. (a) F = 20t – 5t 2 ? ? ? ? (as ? = 0 at t = 0, 6s) ? ? = 36 rad ? 3. (b) Since no external torque act on gymnast, so angular momentum (L=I ) is conserved. After pulling her arms & legs, the angular velocity increases but moment of inertia of gymnast, decreases in, such a way that angular momentum remains constant. 4. (b) The M.I. about the axis of rotation is not constant as the perpendicular distance of the bead with the axis of rotation increases. Also since no external torque is acting. ? t ext = L = constant I? = constant Since, I increases, ? decreases. 5. (b) ....... (1) ....... (2) a 1 = a ....... (3) Acceleration of point b = acceleration of point a ra 1 = a cm – ra ....... (4) Hence, 2ra = a cm 6. (b) Velocity of the tennis ball on the surface of the earth or ground ( where k = radius of gyration of spherical shell = ) Horizontal range AB = Solving we get AB = 2.08 m 7. (d) Initially centre of mass is at the centre. When sand is poured it will Page 3 1. (b) I = 1.2 kg m 2 , E r = 1500 J, a = 25 rad/sec 2 , ? 1 = 0, t = ? As E r From 50 = 0 + 25 t, ? t = 2 seconds 2. (a) F = 20t – 5t 2 ? ? ? ? (as ? = 0 at t = 0, 6s) ? ? = 36 rad ? 3. (b) Since no external torque act on gymnast, so angular momentum (L=I ) is conserved. After pulling her arms & legs, the angular velocity increases but moment of inertia of gymnast, decreases in, such a way that angular momentum remains constant. 4. (b) The M.I. about the axis of rotation is not constant as the perpendicular distance of the bead with the axis of rotation increases. Also since no external torque is acting. ? t ext = L = constant I? = constant Since, I increases, ? decreases. 5. (b) ....... (1) ....... (2) a 1 = a ....... (3) Acceleration of point b = acceleration of point a ra 1 = a cm – ra ....... (4) Hence, 2ra = a cm 6. (b) Velocity of the tennis ball on the surface of the earth or ground ( where k = radius of gyration of spherical shell = ) Horizontal range AB = Solving we get AB = 2.08 m 7. (d) Initially centre of mass is at the centre. When sand is poured it will fall and again after a limit, centre of mass will rise. 8. (a) Here Now, Moment of inertia of the cube about the given axis, 9. (d) Minimum velocity for a body rolling without slipping For solid sphere, ? 10. (c) From conservation of angular momentum about any fix point on the Page 4 1. (b) I = 1.2 kg m 2 , E r = 1500 J, a = 25 rad/sec 2 , ? 1 = 0, t = ? As E r From 50 = 0 + 25 t, ? t = 2 seconds 2. (a) F = 20t – 5t 2 ? ? ? ? (as ? = 0 at t = 0, 6s) ? ? = 36 rad ? 3. (b) Since no external torque act on gymnast, so angular momentum (L=I ) is conserved. After pulling her arms & legs, the angular velocity increases but moment of inertia of gymnast, decreases in, such a way that angular momentum remains constant. 4. (b) The M.I. about the axis of rotation is not constant as the perpendicular distance of the bead with the axis of rotation increases. Also since no external torque is acting. ? t ext = L = constant I? = constant Since, I increases, ? decreases. 5. (b) ....... (1) ....... (2) a 1 = a ....... (3) Acceleration of point b = acceleration of point a ra 1 = a cm – ra ....... (4) Hence, 2ra = a cm 6. (b) Velocity of the tennis ball on the surface of the earth or ground ( where k = radius of gyration of spherical shell = ) Horizontal range AB = Solving we get AB = 2.08 m 7. (d) Initially centre of mass is at the centre. When sand is poured it will fall and again after a limit, centre of mass will rise. 8. (a) Here Now, Moment of inertia of the cube about the given axis, 9. (d) Minimum velocity for a body rolling without slipping For solid sphere, ? 10. (c) From conservation of angular momentum about any fix point on the surface, mr 2 ? 0 = 2mr 2 ? ? ? 11. (a) When n = 0, x = k where k is a constant. This means that the linear mass density is constant. In this case the centre of mass will be at the middle of the rod i.e., at L/2. Therefore (c) is ruled out n is positive and as its value increases, the rate of increase of linear mass density with increase in x increases. This shows that the centre of mass will shift towards that end of the rod where n = L as the value of n increases. Therefore graph (b) is ruled out. The linear mass density With increase in the value of n, the centre of mass shift towards the end x = L such that first the shifting is at a higher rate with increase in the value of n and then the rate decreases with the value of n. These characteristics are represented by graph (a). Page 5 1. (b) I = 1.2 kg m 2 , E r = 1500 J, a = 25 rad/sec 2 , ? 1 = 0, t = ? As E r From 50 = 0 + 25 t, ? t = 2 seconds 2. (a) F = 20t – 5t 2 ? ? ? ? (as ? = 0 at t = 0, 6s) ? ? = 36 rad ? 3. (b) Since no external torque act on gymnast, so angular momentum (L=I ) is conserved. After pulling her arms & legs, the angular velocity increases but moment of inertia of gymnast, decreases in, such a way that angular momentum remains constant. 4. (b) The M.I. about the axis of rotation is not constant as the perpendicular distance of the bead with the axis of rotation increases. Also since no external torque is acting. ? t ext = L = constant I? = constant Since, I increases, ? decreases. 5. (b) ....... (1) ....... (2) a 1 = a ....... (3) Acceleration of point b = acceleration of point a ra 1 = a cm – ra ....... (4) Hence, 2ra = a cm 6. (b) Velocity of the tennis ball on the surface of the earth or ground ( where k = radius of gyration of spherical shell = ) Horizontal range AB = Solving we get AB = 2.08 m 7. (d) Initially centre of mass is at the centre. When sand is poured it will fall and again after a limit, centre of mass will rise. 8. (a) Here Now, Moment of inertia of the cube about the given axis, 9. (d) Minimum velocity for a body rolling without slipping For solid sphere, ? 10. (c) From conservation of angular momentum about any fix point on the surface, mr 2 ? 0 = 2mr 2 ? ? ? 11. (a) When n = 0, x = k where k is a constant. This means that the linear mass density is constant. In this case the centre of mass will be at the middle of the rod i.e., at L/2. Therefore (c) is ruled out n is positive and as its value increases, the rate of increase of linear mass density with increase in x increases. This shows that the centre of mass will shift towards that end of the rod where n = L as the value of n increases. Therefore graph (b) is ruled out. The linear mass density With increase in the value of n, the centre of mass shift towards the end x = L such that first the shifting is at a higher rate with increase in the value of n and then the rate decreases with the value of n. These characteristics are represented by graph (a). 12. (b) Applying angular momentum conservation mV 0 R 0 = (m) (V 1 ) ? v 1 = 2V 0 Therefore, new KE = m (2V 0 ) 2 = 13. (b) 14. (c) Kinetic energy (rotational) K R = Kinetic energy (translational) K T = (v = R?) M.I. (initial) I ring = MR 2 ; ? initial = ? M.I. (new) I' (system) = ?' (system) ? = Solving we get loss in K.E. = 15. (c) After collision velocity of COM of A becomes zero and that of B becomes equal to initial velocity of COM of A. But angular velocity of A remains unchanged as the two spheres are smooth. 16. (c) Velocity of 17. (b) Couple produces purely rotational motion.Read More
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