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A liquid of density p is coming out of a hose pipe of radius a with horizontal speed υ and hits a mesh . 50 % of the liquid passes through the mesh unaffected . 25 % comes back with the same speed .The resultant pressure on the mesh will be:
06
Nov
A liquid of density p is coming out of a hose pipe of radius a with horizontal speed υ and hits a mesh . 50 % of the liquid passes through the mesh unaffected . 25 % comes back with the same speed .The resultant pressure on the mesh will be: coefficient of viscosity of [...]
The top of a water tank is open to air and its water level is maintained. It is giving out 0.74 m^3 water per minute through a circular opening of 2 cm radius in its wall. The depth of the centre of the opening from the level of water in the tank is close to :
06
Nov
The top of a water tank is open to air and its water level is maintained. It is giving out 0.74 m^3 water per minute through a circular opening of 2 cm radius in its wall. The depth of the centre of the opening from the level of water in the tank is close to [...]
Water flows into a large tank with flat bottom at the rate of 10^−4 m^3s^−1. Water is also leaking out of a hole of area 1 cm^2 at its bottom. If the height of the water in the tank remains steady, then this height is :
06
Nov
Water flows into a large tank with flat bottom at the rate of 10^−4 m^3s^−1. Water is also leaking out of a hole of area 1 cm^2 at its bottom. If the height of the water in the tank remains steady, then this height is : then this height is : Water flows into a [...]
Water from a tap emerges vertically downwards with an initial speed of 1.0 ms^−1. The cross-sectional area of the tap is 10^−4 m^2. Assume that the pressure is constant throughout the stream of water and that the flow is steady. The cross-sectional area of the stream 0.15 m below the tap would be (g=10ms^−2 )
06
Nov
Water from a tap emerges vertically downwards with an initial speed of 1.0 ms^−1. The cross-sectional area of the tap is 10^−4 m^2. Assume that the pressure is constant throughout the stream of water and that the flow is steady. The cross-sectional area of the stream 0.15 m below the tap would be (g=10ms^−2 ) [...]
A cubical block of side 0.5 m floats on water with 30% of its volume under water. What is the maximum weight that can be put on the block without fully submerging it under water ? (Take density of water = 10^3 kg/m^3 )
06
Nov
A cubical block of side 0.5 m floats on water with 30% of its volume under water. What is the maximum weight that can be put on the block without fully submerging it under water ? (Take density of water = 10^3 kg/m^3 ) coefficient of viscosity of water =1 mPas). the Reynolds number for [...]
A submarine experiences a pressure of 5.05×10^6Pa at a depth of d1 in a sea When it goes further to a depth of d2. It experiences a pressure of 8.08×10^6Pa. The d2−d1 is approximately (density of water =10^3kg/m^3 and acceleration due to gravity =10 ms^−2)
06
Nov
A submarine experiences a pressure of 5.05×10^6Pa at a depth of d1 in a sea When it goes further to a depth of d2. It experiences a pressure of 8.08×10^6Pa. The d2−d1 is approximately (density of water =10^3kg/m^3 and acceleration due to gravity =10 ms^−2) coefficient of viscosity of water =1 mPas). the Reynolds number [...]
The ratio of surface tensions of mercury and water is given to be 7.5 while the ratio of their densities is 13.6. Their contact angles, with glass, are close to 135 degree and 0 degree , respectively. It is observed that mercury gets depressed by an amount h in a capillary tube of radius r1, while water rises by the same amount h in a capillary tube of radius r2. The ratio,(r2 /r1), is then close to :
06
Nov
The ratio of surface tensions of mercury and water is given to be 7.5 while the ratio of their densities is 13.6. Their contact angles, with glass, are close to 135 degree and 0 degree , respectively. It is observed that mercury gets depressed by an amount h in a capillary tube of radius r1, [...]
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Chapter 7 - Properties of Solids and Liquids
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JEE Mains Physics 2002-2019 Solved Video Solutions
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(r2 /r1) ,
are close to 135 degree and 0 degree ,
is then close to : ,
respectively. It is observed that mercury gets depressed by an amount h in a capillary tube of radius r1 ,
The ratio of surface tensions of mercury and water is given to be 7.5 while the ratio of their densities is 13.6. Their contact angles ,
while water rises by the same amount h in a capillary tube of radius r2. The ratio ,
with glass ,
Water from a pipe is coming at a rate of 100 liters per minute. If the radius of the pipe is 5 cm, the Reynolds number for the flow is of the order of : (density of water =1000 kg/m^3 , coefficient of viscosity of water =1 mPas).
06
Nov
Water from a pipe is coming at a rate of 100 liters per minute. If the radius of the pipe is 5 cm, the Reynolds number for the flow is of the order of : (density of water =1000 kg/m^3 , coefficient of viscosity of water =1 mPas). coefficient of viscosity of water =1 mPas). [...]
A set of 56 tuning forks is arranged in a sequence of increasing frequencies. If each fork gives 4 beats/s with the preceding one and the last fork is found to be an octave higher
06
Nov
A set of 56 tuning forks is arranged in a sequence of increasing frequencies. If each fork gives 4 beats/s with the preceding one and the last fork is found to be an octave higher A set of 56 tuning forks is arranged in a sequence of increasing frequencies. If each fork gives 4 beats/s [...]
A source emitting sound of frequency 180 Hz is placed in front of a wall at distance of 2 m from it. A detector is also placed in front of the wall at the same distance from it.
06
Nov
A source emitting sound of frequency 180 Hz is placed in front of a wall at distance of 2 m from it. A detector is also placed in front of the wall at the same distance from it. A source emitting sound of frequency 180 Hz is placed in front of a wall at distance [...]