A piece of wood is floating in water kept in a bottle. The bottle is connected to an air pump. Neglect the compressibility of water. When more air is pushed into the bottle from the pump, the piece of wood will float with
1. larger part in the water
2. lesser part in the water
3. same part in the water
4. it will sink
A metal cube is placed in an empty vessel. When water is filled in the vessel so that the cube is completely immersed in the water, the force on the bottom of the vessel in contact with the cube:
1. will increase
2. will decrease
3. will remain the same
4. will become zero
1. | \(P_1=P_2=P_3\) | 2. | \(P_1<P_2<P_3\) |
3. | \(P_1=P_2\neq P_3\) | 4. | \(P_2=P_3\neq P_1\) |
A closed cubical box is completely filled with water is accelerated horizontally towards right with an acceleration a. The resultant normal force by the water on the top of the box:
1. passes through the centre of the top.
2. passes through a point to the right of the centre.
3. passes through a point to the left of the centre.
4. becomes zero.
Consider the situation of the previous problem. Let the water push the left wall by a force F1 and the right wall by a force F2
1. F1 = F2
2. F1 > F2
3. F1 < F2
4. The information is insufficient to know the relation between F1 and F2
Previous problem: A closed cubical box is completely filled with water is accelerated horizontally towards right with an acceleration a.
Water enters through end \(A\) with a speed \(v_1\) and leaves through end \(B\) with a speed \(v_2\) of a cylindrical tube AB. The tube is always completely filled with water. In case I the tube is horizontal, in case II it is vertical with the end \(A\) upward and in case III it is vertical with the end \(B\) upward. We have \(v_1=v_2\) for:
1. case I
2. case II
3. case III
4. each one
Water is flowing through a long horizontal tube. Let \(P_A\) and \(P_B\) be the pressures at two points \(A\) and \(B\) of the tube.
1. | \(P_A\) must be equal to \(P_B\). |
2. | \(P_A\) must be greater than \(P_B\). |
3. | \(P_A\) must be smaller than \(P_B\). |
4. | \(P_A\) = \(P_B\) only if the cross-sectional area at A and B are equal. |
Water and mercury are filled in two cylindrical vessels up to the same height. Both vessels have a hole in the wall near the bottom. The velocity of water and mercury coming out of the holes are v1 and v2 respectively.
1. v1 = v2
2. v1 = 13.6 v2
3. v1 = v2/13.6
4. v1 = \(\sqrt{13.6}\)v2
A large cylindrical tank has a hole of area A at its bottom. Water is poured into the tank by a tube of equal cross-sectional area A ejecting water at the speed v.
1. The water level in the tank will keep on rising
2. No water can be stored in the tank
3. The water level will rise to a height v2/2 g and then stop
4. The water level will oscillate