Home
Class 11
PHYSICS
Water is filled in a flask upto a height...

Water is filled in a flask upto a height of `20cm`. The bottom of the flask is circular with radius `10 cm`. If the atmospheric pressure is `1.013xx10^(5)` Pa, find the force exerted by the water on the bottom . Take `g=10 "ms"^(-2)` and density of water `=1000 "kgm"^(-3).`

Promotional Banner

Similar Questions

Explore conceptually related problems

Water is filled in a flask up to a height of 20 cm. The bottom of the flask is circular with radius 10 cm. If the atmospheric pressure is 1.01xx10^5 Pa, find the force exerted by the water on the bottom. Take g=10 ms^-2 and density of water =1000 kgm^-3.

Water is filled in a flask up to a height of 20 cm. The bottom of the flask is circular with radius 10 cm. If the atmospheric pressure is 1.01xx10^5 Pa, find the force exerted by the water on the bottom. Take g=10 ms^-2 and density of water =1000 kgm^-3.

Water is filled in a flask up top a heightof 20 cm. The bottom of the flask is circular with radius 10 cm.If the atmospheric pressure is 1.01xx10^5 Pa, find the force exerted by the water on the bottom. Take g=10 ms^-2 and density of water = 1000 kgm^-3 .

Water is filled in a flask up top a heightof 20 cm. The bottom of the flask is circular with radius 10 cm.If the atmospheric pressure is 1.01xx10^5 Pa, find the force exerted by the water on the bottom. Take g=10 ms^-2 and density of water =1000 kgm^-3 .

Calculate the pressure due to a water column of height 100 m. (Take g=10 ms^(-2) and density of water =10^(3)kg m^(-3)) .

The manometer has a water column difference of 50 cm . If the atmospheric pressure is 10^(5) Pa, find the pressure of the gas in the container .

The manometer has a water column difference of 50 cm . If the atmospheric pressure is 10^(5) Pa, find the pressure of the gas in the container .

A flux is filled upto 20 cm. Bottom of the flux is circular & area is 1 m^2 . Atmospheric pressure is 1.01xx10^5 Pa .Then calculate the amount of pressure applied by water, at the bottom of the flux, (g= 10 m//s^2, p = 1100 kg//m^3)

A beaker of circular ceross sectionof radius 4 cm is filled with mercury up to a height of 10 cm. Find the force exerted by the mercury on the bottom of the beaker. The atmospheric pressure =10^5Nm^-2 . Density of mercury =13600 kgm^-3. Take g10ms^-2

A beaker of circular cross-section of radius 4 cm is filled with mercury up to a height of 10 cm. Find the force exerted by the mercury on the bottom of the beaker. The atmospheric pressure =10^5Nm^-2 . Density of mercury =13600 kgm^-3. Take g10ms^-2