Q. No.If two pieces of metal when immersed in a liquid have equal upthrust on them, then:
1.
Both pieces must have equal weights
2.
Both pieces must have equal densities
3.
Both pieces must have equal volumes
4.
Both are floating in the same depth
The following figure shows the flow of liquid through a horizontal pipe. Three tubes \(A,\) \(B\) and \(C\) are connected to the pipe. The radii of the tubes \(A,\) \(B\) and \(C\) at the junction are respectively \(2~\text{cm},1~\text{cm}\) and \(2~\text{cm}.\) It can be said that:
| 1. | the height of the liquid in the tube \(A\) is maximum. |
| 2. | the height of the liquid in the tubes \(A\) and \(B\) is the same. |
| 3. | the height of the liquid in all three tubes is the same. |
| 4. | the height of the liquid in the tubes \(A\) and \(C\) is the same. |
There is a hole in the bottom of a tank having water. If the total pressure at the bottom is \(3\) atm \((1~\text{atm}=10^5~\text{N}/\text{m}^2),\) then the velocity of water flowing from the hole is:
1. \(\sqrt{400}~~\text{m/s}\)
2. \(\sqrt{600}~~\text{m/s}\)
3. \(\sqrt{60}~~\text{m/s}\)
4. none of these
A square plate of 0.1 m side moves parallel to a second plate with a velocity of 0.1 m/s, both plates being immersed in water. If the viscous force is 0.002 N and the coefficient of viscosity is 0.01 poise, then the distance between the plates in m is:
| 1. | 0.1 | 2. | 0.05 |
| 3. | 0.005 | 4. | 0.0005 |
A spherical ball of radius \(r\) is falling in a viscous fluid of viscosity \(\eta\) with a velocity \(v.\) The retarding viscous force acting on the spherical ball is:
| 1. | inversely proportional to \(r\) but directly proportional to velocity \(v.\) |
| 2. | directly proportional to both radius \(r\) and velocity \(v.\) |
| 3. | inversely proportional to both radius \(r\) and velocity \(v.\) |
| 4. | directly proportional to \(r\) but inversely proportional to \(v.\) |
The pans of a physical balance are in equilibrium. If Air is blown under the right-hand pan then the right-hand pan will:
| 1. | move up | 2. | move down |
| 3. | move erratically | 4. | remain at the same level |
A sniper fires a rifle bullet into a gasoline tank making a hole 53.0 m below the surface of gasoline. The tank was sealed at 3.10 atm. The stored gasoline has a density of 660 . The velocity with which gasoline begins to shoot out of the hole will be:
| 1. | 27.8 ms-1 | 2. | 41.0 ms-1 |
| 3. | 9.6 ms-1 | 4. | 19.7 ms-1 |
A tank is filled with water up to a height \(H.\) The water is allowed to come out of a hole \(P\) in one of the walls at a depth \(D\) below the surface of the water. The horizontal distance \({x}\) in terms of \(H\) and \({D}\) is:
1. \(x = \sqrt{D\left(H-D\right)}\)
2. \(x = \sqrt{\frac{D \left(H - D \right)}{2}}\)
3. \(x = 2 \sqrt{D \left(H-D\right)}\)
4. \(x = 4 \sqrt{D \left(H-D\right)}\)
If a small drop of water falls from rest through a large height h in air, then the final velocity is:
| 1. | \(\propto \sqrt{\mathrm{h}}\) |
| 2. | \(\propto \mathrm{h} \) |
| 3. | \(\propto(1 / h)\) |
| 4. | Almost independent of h |
A block of ice floats on a liquid of density 1.2 in a beaker. The level of liquid when ice completely melts-
1. Remains same
2. Rises
3. Lowers
4. (1), (2) or (3)
© 2025 GoodEd Technologies Pvt. Ltd.