kadali
The horizontal dimensions of the container ... like length and width ... don't make any difference. But the pressure at the bottom is directly proportional to the depth of the liquid, which is ultimately limited by the height of the container.
pressure of liquid on bottom=density*gravitational force*depth :)
The pressure in a liquid at a given depth is called the hydrostatic pressure. This can be calculated using the hydrostatic equation: P = rho * g * d, where P is the pressure, rho is the density of the liquid, g is gravity (9.8 m/s^2) and d is the depth (or height) of the liquid.
The Pressure and depth of a liquid are related by the equation P= dgh., where d is the density, g is the acceleration due to gravity and h is the depth. This value gives us the gauge pressure that is the excess above the atmospheric pressure.This is explainable with Archimedes principal giving the pressure at the base of the column with the formula Sg x H x G
The formula relating the pressure in a liquid to the depth of the liquid is P = P0 + dgh. P is the pressure, P0 is atmospheric pressure, d is the density of the fluid, g is the acceleration of gravity, and h is height below the surface of the water.
They demonstrate that pressure exerted by a liquid depends on the depth of the liquid. The shape of the container is not a factor.
If you were submerged in a liquid more dense than water, the pressure would be correspondingly greater. The pressure due to a liquid is precisely equal to the product of weight density and depth. liquid pressure = weight density x depth. also the pressure a liquid exerts against the sides and bottom of a container depends on the density and the depth of the liquid.
The horizontal dimensions of the container ... like length and width ... don't make any difference. But the pressure at the bottom is directly proportional to the depth of the liquid, which is ultimately limited by the height of the container.
when it is placed in a container and it decreases moving uo . pressure due to the liquid increases with depth from the surface of the liquid
Liquid pressure depends on depth. It can be calculated from liquid density times depth.
pressure of liquid on bottom=density*gravitational force*depth :)
The greater the depth, the greater the pressure.
The pressure exerted by a liquid increases with depth. This is known as hydrostatic pressure and is directly proportional to the density of the liquid. The pressure variation with direction is isotropic, meaning it is the same regardless of the direction taken in the liquid.
Atmospheric pressure Density of the liquid Gravitional field strength in the area the liquid is in The distance from the surface of the liquid i.e. depth Pressure in a liquid=Atmospheric pressure +(Depth X Gravity strength X Density) There might be more I don't know about
consider an enclosed container with liquid filled to the brim, the pressure at any point in the container due to the liquid is given by this formula Pressure = height x density x acceleration due to gravity, and the height we are using here is not the height of this point above the ground, but instead it is the height difference (or simply length) between this point and the top of container, as we are measuring the pressure at this point due to the liquid above. similarly, you can consider a container that is not enclosed but you must remember to include the atmostpheric pressure into the total pressure at the particular point you are measuring. hope this helps =)
At greater depth, the pressure increases, due to the weight of the liquid above.
the pressure of liquid is HDG where H=depth D=density g= acceleration due to gravity thus depth= pressure/density*acceleration due to gravity