A string with constant tension T is deflected through an angle 2θ0 by a smooth fixed pulley. The force on the pulley is

(a) 2T cosθ0
(b) T cosθ0
(c) 2T sinθ0
(d) T sinθ0

Subtopic:  String Constraint |
 67%
To view explanation, please take trial in the course.
NEET 2025 - Target Batch
Hints

                                              

A smooth semicircular wire track of radius R is fixed in a vertical plane as shown. 
One end of a light springs of natural length 3R4 is attached to the lower point O
 of the wire track. A small bead of mass m which can slide on the track, is 
attached to makes an a the other end of the spring. The bead is held
 stationary at point P such that spring makes an angle of 60° with the vertical.
 The spring constant is k = mgR. The restoring force in the spring at that instant 
is-

(a) mg

(b) 14mg

(c) 18mg

(d) 12mg

Subtopic:  Spring Force |
 60%
To view explanation, please take trial in the course.
NEET 2025 - Target Batch
Hints

Traffic is moving at 60 km/hr along a circular track of radius 0.2 km, the correct angle of banking is

1.  tan-1609.8×0.2

2.  tan-160×9.8200

3.  tan-15032200×9.8

4.  tan-1503200×9.8

Subtopic:  Banking of Roads |
 79%
To view explanation, please take trial in the course.
NEET 2025 - Target Batch
Hints
To view explanation, please take trial in the course.
NEET 2025 - Target Batch

advertisementadvertisement

In the figure pulley P1 is fixed and the pulley P2 is movable. If w1=w2, what is the angle between AP2P1? (pulleys are frictionless)

         
1. 30°

2. 60°

3. 150°

4. 120°

Subtopic:  String Constraint |
 53%
To view explanation, please take trial in the course.
NEET 2025 - Target Batch
Hints

A light spring is compressed and placed horizontally between a vertical fixed wall and a toy car which is free to slide over a smooth horizontal table. If the system is released from rest, which graph best represents acceleration \(a\) and distance \(x\) covered by the car?

                                 

1. 2.
3. 4.
Subtopic:  Spring Force |
 56%
To view explanation, please take trial in the course.
NEET 2025 - Target Batch
Hints
To view explanation, please take trial in the course.
NEET 2025 - Target Batch

A rigid ball of mass \(M\) strikes a rigid wall at \(60^{\circ}\) and gets reflected without loss of speed, as shown in the figure. The value of the impulse imparted by the wall on the ball will be:
         

1. \(Mv\) 2. \(2Mv\)
3. \(\dfrac{Mv}{2}\) 4. \(\dfrac{Mv}{3}\)
Subtopic:  Newton's Laws |
 76%
From NCERT
NEET - 2016
To view explanation, please take trial in the course.
NEET 2025 - Target Batch
Hints
Links
To view explanation, please take trial in the course.
NEET 2025 - Target Batch

advertisementadvertisement

Which one of the following statements is incorrect?

1. Rolling friction is smaller than sliding friction.
2. The limiting value of static friction is directly proportional to the normal reaction.
3. Frictional force opposes the relative motion.
4. The coefficient of sliding friction has dimensions of length.
Subtopic:  Friction |
 78%
From NCERT
NEET - 2018
To view explanation, please take trial in the course.
NEET 2025 - Target Batch
Hints
Links
To view explanation, please take trial in the course.
NEET 2025 - Target Batch

A block of mass \(m\) is placed on a smooth inclined wedge \(ABC\) of inclination \(\theta\) as shown in the figure. The wedge is given an acceleration '\(a\)' towards the right. The relation between \(a\) and \(\theta\) for the block to remain stationary on the wedge is:
          
1. \(a = \dfrac{g}{\mathrm{cosec }~ \theta}\)
2. \(a = \dfrac{g}{\sin\theta}\)
3. \(a = g\cos\theta\)
4. \(a = g\tan\theta\)

Subtopic:  Application of Laws |
 79%
From NCERT
NEET - 2018
To view explanation, please take trial in the course.
NEET 2025 - Target Batch
Hints
Links
To view explanation, please take trial in the course.
NEET 2025 - Target Batch

A car is negotiating a curved road of radius \(R\). The road is banked at an angle \(\theta\). The coefficient of friction between the tyre of the car and the road is \(\mu_s\). The maximum safe velocity on this road is:
1. \(\sqrt{\operatorname{gR}\left(\dfrac{\mu_{\mathrm{s}}+\tan \theta}{1-\mu_{\mathrm{s}} \tan \theta}\right)}\)
2. \(\sqrt{\frac{\mathrm{g}}{\mathrm{R}}\left(\dfrac{\mu_{\mathrm{s}}+\tan \theta}{1-\mu_{\mathrm{s}} \tan \theta}\right)}\)
3. \(\sqrt{\frac{\mathrm{g}}{\mathrm{R}^2}\left(\dfrac{\mu_{\mathrm{s}}+\tan \theta}{1-\mu_{\operatorname{s}} \tan \theta}\right)}\)
4. \(\sqrt{\mathrm{gR}^2\left(\dfrac{\mu_{\mathrm{s}}+\tan \theta}{1-\mu_{\mathrm{s}} \tan \theta}\right)}\)

Subtopic:  Banking of Roads |
 88%
From NCERT
NEET - 2016
To view explanation, please take trial in the course.
NEET 2025 - Target Batch
Hints
Links
To view explanation, please take trial in the course.
NEET 2025 - Target Batch

advertisementadvertisement

Three blocks \(\mathrm{A}\), \(\mathrm{B}\), and \(\mathrm{C}\) of masses \(4~\text{kg}\), \(2~\text{kg}\), and \(1~\text{kg}\) respectively, are in contact on a frictionless surface, as shown. If a force of \(14~\text{N}\) is applied to the \(4~\text{kg}\) block, then the contact force between \(\mathrm{A}\) and \(\mathrm{B}\) is: 
          
1. \(2~\text{N}\)
2. \(6~\text{N}\)
3. \(8~\text{N}\)
4. \(18~\text{N}\)

Subtopic:  Tension & Normal Reaction |
 81%
From NCERT
NEET - 2015
To view explanation, please take trial in the course.
NEET 2025 - Target Batch
Hints
Links
To view explanation, please take trial in the course.
NEET 2025 - Target Batch