5000 mm = 5 m
Density of water = 1000 kgm-3
Gravitational acceleration = 9.81 ms-2
Pressure at base (nm-2) = height of water column * density of water * gravitational acceleration
Pressure (nm-2) = 5 * 1000 * 9.81
Pressure = 49,050 nm-2 (49.05 kNm-2)
The question is unclear as to whether you require the answer in units of bar or atmospheres so both are provided:
Pressure in bar = 0.4905
Pressure in atmospheres = 0.484
16.387 cc is equal to one cubic inch of water or anything else.
ODS means octadecylsilane and BDS means base deactivated silica.
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
Distilled water is not a base.
You can't. In addition to the cylinder's diameter, the pressure at its base also depends on the density and depth of the fluid in the cylinder ... which gives you the weight of fluid resting on the base area. The pressure alone is not enough information to allow you to calculate the diameter.
The diameter of the water column does not affect the pressure.It is the height of the column that determines the pressure at the base.(and also the barometric pressure and temperature).
Are you asking hydrostatic (standing still) or if the water is under pressure such as the pressure at the base of a riser based on the height of the column of water?
Every 2.3077 feet of water in a column increases the water pressure at the bottom of the column by 1 pound per square inch.A 39 foot column of water with a pressure of 120 psi at the base will have a pressure exerted on its top surface of 103.1 psi.39 ft/ 2.3077 ft/1 psi = 16.9 psi ; 120 psi -16.9 psi = 103.1 psievery meter of water in a column increases the pressure at the base of the column by 0.1 kg./ sq. cm (or 1 kilopascal)A 12 meter column of water exerts a pressure at its base of 12 kPa. (or 1.2 kg/sq. cm)
You need to know how high the water column is to calculate the pressure it exerts at its base! For example, a column of water 1 metre deep would exert a pressure of 9.81 kPa at its base (density x gravity x depth - 1000 * 9.81 * 1). This would be equal to approx 1.42 PSI.
10 feet x 0.433 psi/ft = 4.33 psi at the base of the cylinder.
Assumptions:Density of water = 1000 kgm-3.Gravitational acceleration = 9.81 ms-2To calculate the pressure head of a 1 m depth of water, it is necessary to find the unit weight:Unit Weight = Density x gravityUnit Weight = 9810 Nm-3To calculate the pressure head at the base of the column of water:Pressure = Unit Weight x DepthPressure = 9810 x 1Pressure = 9810 PaThe resulting pressure is 9.81 kPa.
I must assume you mean uniterrupted column of water! The maximum suction lift of a column of water is the height of a column of water (inside a vertical pipe for instance) that can be supported by atmospheric pressure i.e. approx 14.69psi or 760mm Mercury. You should be aware that suction does not cause water to lift. Suction produced by various kinds of pump merely removes air from above the column of water and this allows atmospheric pressure to act upon the base of the water column. The water column is therefore pushed upwards by atmospheric pressure from below rather than pulled up by suction from above. The density, vapour pressure and surface tension of water vary slightly with temperature and atmospheric pressure also varies slightly with weather conditions. Thus the measured height of the water column may vary slightly according to the conditions prevailing when making the measurement. A good approximation at room temperature is 33 feet or 10 metres. Dan Hanlon
The water pressure depends ONLY on the height, and the density of the liquid - not on the number of gallons. You basically calculate the weight of a vertical column of that height, and divide by the base area. The column can be of any cross section - for example a square centimeter, a square meter, or a square foot. (For water, the pressure is about 1 bar for every 10 meters.)
The pressure that water exerts on the walls of the dam is proportional to the depth of the water or you might say the height of the column of water from the base of the dam. The hydraulic height is the same as the depth of the water to the bottom of the dam.
As the depth of the fluid increases, the pressure increases. To explain this mathematicaly you consider the Sg of the fluid times the height of the column multiplied by gravity will give you the pressure at the base of the column
16.387 cc is equal to one cubic inch of water or anything else.
Trajan's tomb was in reality Trajan's column. His ashes were buried in the base of the column.Trajan's tomb was in reality Trajan's column. His ashes were buried in the base of the column.Trajan's tomb was in reality Trajan's column. His ashes were buried in the base of the column.Trajan's tomb was in reality Trajan's column. His ashes were buried in the base of the column.Trajan's tomb was in reality Trajan's column. His ashes were buried in the base of the column.Trajan's tomb was in reality Trajan's column. His ashes were buried in the base of the column.Trajan's tomb was in reality Trajan's column. His ashes were buried in the base of the column.Trajan's tomb was in reality Trajan's column. His ashes were buried in the base of the column.Trajan's tomb was in reality Trajan's column. His ashes were buried in the base of the column.