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A circular ring and a solid sphere having same radius roll down on an inclined plane from rest without slipping. The ratio of their velocities when reached at the bottom of the plane is sqrtfracx5 where x =

Numerical Answer Type:
Enter a numerical value Answer: 3.5 to 4 +4 marks

Solution & Explanation

### Related Formula Velocity of a rolling body from mechanical energy conservation: v = sqrtfrac2gh1 + frack^2R^2 ### Core Logic Evaluate radius of gyration factor coefficients: 1. For a circular ring: frack^2R^2 = 1 2. For a solid sphere: frack^2R^2 = frac25 ### Step 1: Compute Velocity Expressions v_textring = sqrtfrac2gh1 + 1 = sqrtgh v_textsphere = sqrtfrac2gh1 + frac25 = sqrtfrac10gh7 ### Step 2: Calculate the Velocity Ratio fracv_textringv_textsphere = fracsqrtghsqrtfrac10gh7 = sqrtfrac710 = sqrtfrac3.55 Matching with the prompt expression format sqrtfracx5 reveals: x = 3.5 Rounding to the nearest integer yields 4. ### Pattern Recognition Objects with lower mass concentration near the center (lower frack^2R^2 like the sphere) convert gravitational potential energy into translational kinetic energy more efficiently, rolling faster than hollow equivalents. ### Evaluation Rubric / Model Answer null ### Chapter Mix Class 11 Physics: System of Particles and Rotational Motion

More System of Particles and Rotational Motion Previous-Year Questions — Page 4

Q11 2025 Rolling Motion
A uniform solid cylinder of mass 'm' and radius 'r' rolls along an inclined rough plane of inclination 45^circ If it starts to roll from rest from the top of the plane then the linear acceleration of the cylinder axis will be :-
  • A. frac1sqrt2 g
  • B. frac13sqrt2 g
  • C. fracsqrt2 g3
  • D. sqrt2 g

Solution

### Related Formula The linear acceleration a for pure rolling motion down an incline profile is: a = fracgsintheta1 + fracImr^2 ### Core Logic For a uniform solid cylinder, the moment of inertia around its central axis is: I = frac12mr^2 implies fracImr^2 = frac12 ### Step 1: Calculating Acceleration Substitute theta = 45^circ and the cylinder inertial factor into the formula : a = fracgsin 45^circ1 + frac12 = fracfracgsqrt2frac32 a = frac2g3sqrt2 = fracsqrt2g3 ### Pattern Recognition Solid cylinder rolls with acceleration matching frac23 gsintheta. Since sin 45^circ = frac1sqrt2, this simplifies directly to fracsqrt2g3. ### Evaluation Rubric / Model Answer null ### Chapter Mix Class 11 Physics: System of Particles and Rotational Motion
Q17 2025 Torque and Equilibrium
A uniform rod of mass 250mathrmg having length 100mathrmcm is balanced on a sharp edge at 40mathrmcm mark[cite: 150, 151]. A mass of 400mathrmg is suspended at 10mathrmcm mark. To maintain the balance of the rod, the mass to be suspended at 90mathrmcm mark, is [cite: 154, 156]
  • A. 300mathrmg
  • B. 190mathrmg
  • C. 200mathrmg
  • D. 290mathrmg

Solution

### Related Formula For rotational equilibrium, the \sum of all counter-clockwise torques about the pivot point must exactly balance the \sum of all clockwise torques: sum tau_textpivot = 0 implies sum (m_i cdot g cdot x_i) = 0 ### Core Logic The rod is uniform, meaning its mass (250text g) acts exactly at its geometric center of mass, the 50text cm mark[cite: 150, 151]. Let the pivot point be the sharp edge at the 40text cm mark . Calculate the relative lever arms from the pivot [cite: 775, 776, 777]: * 400text g mass at 10text cm mark: lever arm = 40 - 10 = 30text cm (counter-clockwise) * 250text g rod mass at 50text cm mark: lever arm = 50 - 40 = 10text cm (clockwise) * Unknown mass M at 90text cm mark: lever arm = 90 - 40 = 50text cm (clockwise) Setting up the torque balance equation: 400 times 30 = (250 times 10) + (M times 50) 12000 = 2500 + 50M 50M = 9500 implies M = frac950050 = 190text g ### Step 1: Visual Context The structural layout of forces acting on the balanced rod system is shown below:
Torque and Equilibrium balancing diagram for Q17
Torque and Equilibrium balancing diagram for Q17
### Pattern Recognition Never forget to include the weight of a uniform rod itself in equilibrium equations. It is a common oversight to omit the rod's mass, which always acts at its geometric center. ### Evaluation Rubric / Model Answer null ### Chapter Mix Class 11 Physics: System of Particles and Rotational Motion

More System of Particles and Rotational Motion Questions — jee_main_2025_04_april_morning

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