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Physics NEET MCQ
Centre Of Mass And Rotational Motion. Mcq
Quiz 8
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Q.1
An automobile moves on a road with a speed of54 kmh-The radius of its wheels is 0.45 m and the moment of inertia of the wheel about its axis of rotation is 3kgmIf the vehicle is brought to rest in 15s, the magnitude of average torque transmitted by its brakes to wheel is :-
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a) 2.86 kg m2s-2
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b) 6.66 kg m2s-2
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c) 8.58 kg m2s-2
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d) 10.86 kg m2s-2
Explanation
54kmh-1 = 15m/s v= ωr ∴ω= v /r = 15/0.45 τ = Iα Answer:(b)
Q.2
Point masses m1 and m2 are placed at the opposite ends of a rigid rod of length L, and negligible mass. The rod is to be set rotating about an axis perpendicular to it. The position of point P on this rod through which the axis should pass so that the work required to set the rod rotating with angular velocity ω0 is minimum is given by … [ Re AIPMT 2015]
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a)
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b)
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c)
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d)
Explanation
The position of point P on the rod through which the axis should pass so that the work required to set the rod rotating with minimum angular velocity ωo is their centre of mass m1x = m2(L-x) It can be proved as follows τ ∝ I as in given problem minimum angular velocity ωo For torque to be minimum, we can differentiate it with x, as x is variable and we want to find it Answer:(a)
Q.3
Two stones of masses m and 2 m are whirled in horizontal circles, the heavier one in a radius r/2andthe lighter one in radius r. The tangential speed of lighter stone is n times that of the value of heavier stone when they experience same centripetal forces. The value of n is : … [ Re AMPT 2015]
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a) 1
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b) 2
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c) 3
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d) 4
Explanation
Same centripetal force V and v’ is tangential velocity and given v = nv, n =2 Answer:(b)
Q.4
From a disc of radius R and mass M, a circular hole of diameter R, whose rim passes through the centre is cut. What is the moment of inertia of the remaining part of the disc about a perpendicular axis, passing through the centre?
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a)
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b)
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c)
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d)
Explanation
Disc Moment of inertia =I Momentum of remaining part = I1 Moment of inertia of small disc w.r.t centre of big disc = I2 Now I = I1 + I2; I1 = I – I2 Answer:(b)
Q.5
A uniform circular disc of radius 50 cm at rest is free to turn about an axis which is perpendicular to its plane and passes through its centre. It is subjected to a torque which produces a constant angular acceleration of 2.0 rad s–Its net acceleration in ms–2 at the end of 2.0 s is approximately :
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a) 8.0
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b) 7.0
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c) 6.0
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d) 3.0
Explanation
We will assume that particle is at the circumference of disc ar is the radial acceleration or centripetal acceleration aT is the tangential acceleration ar = 0.5×16= 8 aT= 2×0.5 =1 Answer:(a)
Q.6
A disk and a sphere of same radius but different masses roll off on two inclined planes of the same altitude and length. Which one of the two objects gets to the bottom of the plane first ?
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a) Disk
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b) Sphere
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c) Both reach at the same time
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d) Depends on their masses
Explanation
More the acceleration lesser is the time Thus more is K2/R2 less is the acceleration For disc K2/R2 = 0.5 For sphere K2/R2 = 0.4 As acceleration of sphere is more than disc, sphere will reach bottom first Answer:(b)
Q.7
A particle of mass 10 g moves along a circle of radius 6.4 cm with a constant tangential acceleration. What is the magnitude of this acceleration if the kinetic energy of the particle becomes equal to 8 × 10–4 J by the end of the second revolution after the beginning of the motion?
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a) 0.1 m/s2
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b) 0.15 m/s2
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c) 0.18 m/s2
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d) 0.2 m/s2
Explanation
v2 = u2+ 2ats (s = 4πR as two revolution) 0.4 = 0 +2 at (4π×6.4×10-2) Answer:(a)
Q.8
What is the minimum velocity with which a body of mass m must enter a vertical loop of radius R so that it can complete the loop ? [ AIPMT 2016]
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a) √(gR)
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b) √(2gR)
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c) √(3gR)
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d) √(5gR)
Explanation
if the body has minimum velocity of √(5gr) at the lowest point of vertical circle, it will complete the circle. Answer:(d)
Q.9
A car is negotiating a curved road of radius R. The road is banked at an angle θ. the coefficient of friction between the tyres of the car and the road is µs. The maximum safe velocity on this road is … [ AIPMT 2015]
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a)
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b)
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c)
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d)
Explanation
Form the formula for motion of vehicle on Banked road Answer:(b)
Q.10
In the given figure, a = 15 m/s2 represents the total acceleration of a particle moving in the clockwise direction in a circle of radius R = 2.5 m at a given instant of time. The speed of the particle is … [ NEET II – 2016]
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d) 5.0 m/s
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a) 5.7 m/s
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b) 6.2 m/s
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c) 4.5 m/s
Explanation
Acceleration towards centre = acos30 v2=aRcos30 v= 5.7 m/s Answer:(a)
Q.11
Two rotating bodies A and B of masses m and 2mwith moments of inertia IA and IB (IB > IA) have equal kinetic energy of rotation. If LA and LB be their angular momenta respectively, then … [NEET II -2016] a) b) c) d)
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a) LB > LA
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b) LA > LB
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c) LA = LB/2
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d) LA = 2LB
Explanation
Since IB > IA ∴ LB > LA Answer:(a)
Q.12
A solid sphere of mass m and radius R is rotating about its diameter. A solid cylinder of the same mass and same radius is also rotating about its geometrical axis with an angular speed twice that of the sphere. The ratio of their kinetic energies of rotation (Esphere / Ecylinder) will be …[NEET II – 2016]
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a) 1 : 4
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b) 3 : 1
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c) 2 : 3
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d) 1 : 5
Explanation
Answer:(d)
Q.13
A light rod of length l has two masses m1 and m2 attached to its two ends. The moment of inertia ofthe system about an axis perpendicular to the rodand passing through the centre of mass is .. [ NEET II -2016]
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a)
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b)
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c)
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d)
Explanation
m1x = m2(l-x) m1x = m2l - m2x Similarly Answer:(c)
Q.14
One end of string of length l is connected to a particle of mass ‘m’ and the other end is connected to a small peg on a smooth horizontal table. If the particle moves in circle with speed ‘v’, the net force on the particle (directed towards center) will be(T represents the tension in the string)
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a) T
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b)
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c)
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d) zero
Explanation
Centripetal force is provided by tension Answer:(a)
Q.15
Two discs of same moment of inertia rotating about their regular axis passing through centre and perpendicular to the plane of disc with angular velocities ω1 and ωThey are brought into contact face to face coinciding the axis of rotation. The expression for loss of energy during this process is … [ NEET 2017]
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a)
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b)
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c)
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d)
Explanation
According to law of conservation of angular momentum Iω1 + Iω2 = 2Iω ω = (ω1 + ω2)/2 Initial kinetic energy Loss in energy Answer:(b)
Q.16
A rope is wound around a hollow cylinder of mass3 kg and radius 40 cm. What is the angular acceleration of the cylinder if the rope is pulled with a force of 30 N? [ NEET 2017]
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a) 25 m/s2
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b) 0.25 rad/s2
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c) 25 rad/s2
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d) 5 m/s2
Explanation
τ=Iα F×R=MR2α 30 × 0.4 = 3 (0.4)2α α = 25 rad/s2 Answer:(c)
Q.17
A hoop of radius r and mass m rotating with an angular velocity ω0 is placed on a rough horizontal surface. The initial velocity of the centre of the hoop is zero. What will be the velocity of the centre of the hoop when it ceases to slip ? [ IIT mains 2013]
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a) (rω0)/4
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b) (rω0)/3
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c) (rω0)/2
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d) rω0
Explanation
From law of conservation of momentum Li = Lf Iω0 = Iω + mvr And v = ωr m r2 ω0 = mr2ω + mvr = 2mvr v=(rω0)/2 Answer:(c)
Q.18
A wire, which passes through the hole in a small bead, is bent in the form of quarter of a circle. The wire is fixed vertically on ground as shown in the figure. The bead is released from near the top of the wire and it slides along the wire without friction. As the bead moves from A to B, the force it applies on the wire is …[ IIT Advance 2014]
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a) always radially outwards.
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b) always radially inwards.
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c) radially outwards initially and radially inwards later.
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d) radially inwards initially and radially outwards later.
Explanation
As shown in figure force on the wire = Now as θ goes on increasing mgcosθ decreases and (mv2)/R increases thus Initially force on wire inward and then outward with increased v option “d” correct We can calculate the angle after which force become radially out ward Loss of potential energy = gain in kinetic energy When F = 0 inward and outward force is zero 3mgcosθ=2mg cosθ=2/3 cosθ ≥2/3 force out ward Answer:(d)
Q.19
Two independent harmonic oscillators of equal mass are oscillating about the origin with angular frequencies ω1 and ω2 and have total energies E1 and E2, respectively. Then variations of their momenta p with positions x are shown in the figures. If a/b=n2 and a/R=n then the correct equation(s) is(are) … [ IIT Advance 2015 ]
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a)
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b)
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c)
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d)
Explanation
At extreme position energy is only potential energy At equilibrium position energy is only kinetic energy Similarly mω2 =1 …(ii) From (i) and (ii) Answer:(d)
Q.20
A ring of mass M and radius R is rotating with angular speed ω about a fixed vertical axis passing through its centre O with two point masses each of mass M/8 at rest at O. These masses can move radially outwards along two massless rods fixed on the ring as shown in the figure. At some instant the angular speed of the system is 8ω/9 and one of the masses is at a distance of 3R/5 from O. At this instant the distance of the other mass from O is …[IIT Advantage 2015]
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a) 2R/3
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b) R/3
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c) 3R/5
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d) 4R/5
Explanation
Let the other mass be at a distance x from the centre. Conserving angular momentum about the axis : on solving x =4R/5 Answer:(d)
Q.21
More than one correct option. The position vector of a particle of mass m is given by the following equation r(t) = αt3 i + βt2j. Where α = 10/3 m s-3, β = 5 m s-2 and m = 0.1 kg. At t = 1 s, which of the following statement(s) is(are) true about the particle?
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a) The velocity is given by v = (10i + 10j ) m/s
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b) The angular momentum L with respect to the origin is given by
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c) The force is given by F = (i + 2j)N
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d) The torque τ with respect to the origin is given by
Explanation
Derivative of r gives formula for v Option “a” correct Derivative of v gives acceleration Force = ma = 0.1(20i + 10j)=2i + j N Option “c” wrong Angular momentum L = m(r × v ) Angular momentum = (-5/3) k Option b correct Torque Option d correct Answer:(a, b, d)
Q.22
More than one correct option. Two thin circular discs of mass m and 4m, having radii of a and 2a, respectively, are rigidly fixed by a massless, rigid rod of length l=a√24 through their centres. This assembly is laid on a firm and flat surface, and set rolling without slipping on the surface so that the angular speed about the axis of the rod is ω. The angular momentum of the entire assembly about the point ‘O’ is L (see the figure). Which of the following statement(s) is(are) true? [IIT Advance 2016]
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a) The magnitude of angular momentum of the assembly about its centre of mass is
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b) The centre of mass of the assembly rotates about the z-axis with an angular speed of ω/5
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c) The magnitude of the z-component of L is 55 ma2ω
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d) The magnitude of angular momentum of centre of mass of the assembly about the point O is ma2ω
Explanation
Connecting rod is mass less and do not rotate about its axis. It is given that set rolling without slipping on the surface . So sin component of angular velocity will be the angular velocity along Z axis Option a Axis of rotation is passing through centre of mass. Not considered axis perpendicular to rod. But axis of rotation of disc Moment of inertia of disc = mR2/2 Angular momentum L = I ω option a correct Angular velocity of CM = angular velocity of any of the disc. Since set rolling without slipping on the surface . So sin component of angular velocity will be the angular velocity along Z axis X2 = l2 + a2 X2 = 24a2 + a2 X=5a Sinθ = a/x = a/5a = 1/5 Angular velocity along z axis is ωsinθ =ω/5 Option b correct , c is wrong and d is wrong as component of ω along z axis is ωsinθ Answer:(a, b)
Q.23
PARAGRAPH [IIT Advance 2016] A frame of reference that is accelerated with respect to an inertial frame of reference is called a non-inertial frame of reference. A coordinate system fixed on a circular disc rotating about a fixed axis with a constant angular velocity ω is an example of a non-inertial frame of reference. The relationship between the force Frot experienced by a particle of mass m moving on the rotating disc and the force Fin experienced by the particle in an inertial frame of reference is Where Vrot is the velocity of the particle in the rotating frame of reference and is the position vector of the particle with respect to the centre of the disc. Now consider a smooth slot along a diameter of a disc of radius R rotating counter-clockwise with a constant angular speed ω about its vertical axis through its centre. We assign a coordinate system with the origin at the center of the disc, the x-axis along the slot, the y-axis perpendicular to the slot and the z-axis along the rotation axis ω= ωk . A small block of mass m is gently placed in the slot at r =R/2 i at t = 0 and is constrained to move only along the slot. Q237A) The distance r of the block at time t is
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a)
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b)
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c)
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d)
Explanation
Terms in Frot is Fin + 2m(Vrot × ω) represents the normal reactions Fin=N1= mgk Another normal reaction Total reaction Answer:(d)
Q.24
More than one correct option. A block of mass M has a circular cut with a frictionless surface as shown. The block rests on the horizontal frictionless surface of a fixed table. Initially the right edge of the block is at x = 0, in a co-ordinate system fixed to the table. A point mass m is released from rest at the topmost point of the path as shown and it slides down. When the mass loses contact with the block, its position is x and the velocity is v. At that instant, which of the following options is/are correct ? [ IIT Advance 2017]
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a) The x-component of dispalcement of the centre of mass of the block M is -mR/(m+M)
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b) The position of the point mass is
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c) The velocity of the point mass m is
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d) The velocity of the block M is
Explanation
Small object is slipping and not rolling thus object will leave the curved surface at end of the path Conservation of centre of mass, centre of mass of system will not change The small object be at a distance x from x=0 M is moved by -x final position of m =- x , initial position –R Change in possition of m = final position – initial position = (-x) –(-R) = R - x (option b is wrong) Since change in C.M. of system = 0 Mx = m(R-x) Option a is correct Option c From law of conservation of momentum Now loss of P.E. of m = gain in K.E. of m + gain in K.E. of M Option c is correct Velocity of M = Option d is wrong Answer:(a,c)
Q.25
Consider regular polygons with number of sides n = 3, 4, 5 ..... as shown in the figure. The center of mass of all the polygons is at height h from the ground. They roll on a horizontal surface about the leading vertex without slipping and sliding as depicted. The maximum increase in height of the locus of the center of mass for each polygon is Δ. Then Δ depends on n and h as : …[ IIT Advance 2017]
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a)
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b)
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c)
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d)
Explanation
All sheps are symmetric, hence CM is at geometric centre When polygon rotate and polygone atten position shown by dotted line then centre of mass is at height bo, Now bo = h/cosθ As θ = π/n Answer:(c)
Q.26
More than one correct option A rigid uniform bar AB of length L is slipping from its vertical position on a frictionless floor (as shown in the figure). At some instant of time, the angle made by the bar with the vertical is θ. Which of the following statements about its motion is/are correct ? [ IIT Advance 2017]
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a) When the bar makes an angle θ with the vertical, the displacement of its midpoint from the initial position is proportional to (1 – cosθ)
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b) The midpoint of the bar will fall vertically downward
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c) Instantaneous torque about the point in contact with the floor is proportional to sinθ
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d) The trajectory of the point A is a parabola
Explanation
Initial position of central point L/2 Mid point will be located at position M, Distance OM Option a correct No force is acting along x at mid point and cm is located thus option b is correct Torque = Force ×perpendicular distance between the line of force and fix point Torque = mg OB = Mg (L/2) sinθ [ Option c wrong ] Centre of mass follows straight path Position M = (L/2) cosθ Position of point A y-axis position depends on position of B thus y= Lsin(π/2 –θ) = Lcosθ x-axis position depends on position of M as M is falling vetically down thus x= L/2 sinθ Now cos2θ + sin2θ = 1 Thus trajectory is ellips [ Option d is wrong] Answer:(a, b)
Q.27
A wheel of radius R and mass M is placed at the bottom of a fixed step of height R as shown in the figure. A constant force is continuously applied on the surface of the wheel so that it just climbs the step without slipping. Consider the torque τ about an axis normal to the plane of the paper passing through the point Q. Which of the following options is/are correct ? [ IIT Advcance 2017]
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a) If the force is applied normal to the circumference at point X then τ is constant
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b) If the force is applied tangentially at point S then τ =0 but the wheel never climbs the step
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c) If the force is applied normal to the circumference at point P then τ is zero
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d) If the force is applied at point P tangentially then τ decreases continuously as the wheel climbs
Explanation
If force is applied at point X normal line of action passes through centre of sphere torque produced in zero. Thus torque is constant [Option a correct] τ ≠ 0 if force is tangential at S [ Option b wrong] Force applied normally at point P, torque due to force is zero zero [ Option c correct] If force is applied tangentially the torque is constant as F is constant [ Option d correct] Answer:(a, c)
Q.28
PARAGRAPH -2 One twirls a circular ring (of mass M and radius R) near the tip of one's finger as shown in FigureIn the process the finger never loses contact with the inner rim of the ring. The finger traces out the surface of a cone, shown by the dotted line. The radius of the path traced out by the point where the ring and the finger is in contact is r. The finger rotates with an angular velocity ωThe rotating ring rolls without slipping on the outside of a smaller circle described by the point where the ring and the finger is in contact (Figure 2). The coefficient of friction between the ring and the finger is μ and the acceleration due to gravity is g. Q242A) The total kinetic energy of the ring is
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a)
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b)
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c)
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d)
Explanation
Normal force is produced due to centripital force. Produced because of circular path followed by C.M of ring around small circle of radius R. with velocity v Now Mg = f= µN Answer:(b)
Q.29
A car is negotiating a curved road of radius R. The road is banked at an angle θ. the coefficient of friction between the tyres of the car and the road is µs. The maximum safe velocity on this road is … [ AIPMT 2015]
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a)
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b)
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c)
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d)
Explanation
Form the formula for motion of vehicle on Banked road Answer:(b)
Q.30
A particle is projected with 200 m/s at an angle 60°. At the highest point, it explodes into three parts of equal masses. One goes vertically upwards with velocity 100 m/s, second particle goes vertically downwards. Then the velocity of the third particle will be..[ AFMC 1997]
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a)200 m/s
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b) 300 m/s
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c)120 m/s with 60° angle
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d)200 m/s with 30°angle
Explanation
At highest point velocity of particle is vcosθ=200 cos 60=100 m/sLet the mass of particle be 3mIt is given that two particles of equal mass and same magnitude of velocity goes opposite to each other one goes up while other goes down, thus they cancel each other momentum.refer figure belowNow the last fraction of mass will have momentum equal to the momentum of particle before explosion∴ 3m(100)=m(v') according to law of conservation of energy∴ v'=300 m/s along x axis Answer: (b)
0 h : 0 m : 1 s
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