A cylindrical container with a cross sectional area of 61.2 cm^2 holds a fluid of density 846 kg/m^3. At the bottom of the container the pressure is 126 kPa. (a) What is the depth of the fluid? (b) Find the pressure at the bottom of the container after an additional 2.05 X 10^-3 m^3 of this fluid is added to the container. Assume that no fluid spills out of the container.
A cylindrical container with a cross sectional area of 61.2 cm^2 holds a fluid of density...
A cylindrical container with a cross-sectional area of 60.2cm2 holds a fluid of density 786kg/m3 . At the bottom of the container the pressure is 119kPa . Assume Pat = 101 kPa. What is the depth of the fluid? Find the pressure at the bottom of the container after an additional 2.35
Part (a) The fluid has a density of 920 kg/m, and the tube has a cross-sectional area that is much smaller than the cross-sectional area of the higher container. Calculate the speed at which the fluid flows out of the tube at point Z. _______ m/s The fluid has a density of 920 kg/m, and the tube has a cross-sectional area that is much smaller than the cross-sectional area of the higher container. Calculate the speed at which the fluid...
Mercury is added to a cylindrical container to a depth d and then the rest of the cylinder is filled with water. If the cylinder is 0.7 m tall and the pressure at the bottom is 1.2 atmospheres, determine the depth of the mercury. (Assume the density of mercury to be 1.36 times 10^4 kg/m^3.) m
(a) A large, open at the top, upright cylindrical tank contains a brine with a density of 1.23 x 103 kg/m. If the air pressure is 101.3 kPa, determine the absolute pressure (in Pa) in the fluid at a depth of 27.0 m. 1269.16 The absolute pressure at any point in the fluid is the sum of atmospheric pressure and the pressure due to the depth of the fluid. How can you account for the pressure due to the depth...
A glass tube of cross sectional area 1.3 × 10 4m2 is partially filled with water. An oil with a density of 810 kg ms is slowly with the water and floats on top of it. The height of the oil above the water's surface is l 1 cn. oned into the tube so that does not mi (a) By how much does the pressure change at a depth of 14 cm below the water's surface after the oil s...
A container of cross-sectional area 112 cm2 contains liquid of density 1.85 g/cm3 to a height of 6.60 cm above a small hole of area 1.00 cm2 in the side=2
(a) A large, open at the top, upright cylindrical tank contains fuel oil with a density of 0.890 x 103 kg/m². If the air pressure is 101.3 kPa, determine the absolute pressure (in Pa) in the fluid at a depth of 32.5 m. 283465x The absolute pressure at any point in the fluid is the sum of atmospheric pressure and the pressure due to the depth of the fluid. Did you remember to account for atmospheric pressure? Pa (b) Determine...
Solve the following problems please A container is filled to a depth of 19.0 cm with water. On top of the water floats a 35.0-cm-thick layer of oil with specific gravity 0.900. What is the absolute pressure at the bottom of the container? A cube of wood having an edge dimension of 18.9 cm and a density of 645 kg/m3 floats on water, What is the distance from the horizontal top surface of the cube to the water level? what...
The next three questions refer to a vertical cylindrical beaker holding water. The density of water is 1.0 g/cm2. The volume of a cylinder is TR’H, where is the radius of the cylinder and H is the height. Question 10 2 pts If the beaker holds 1.82 kg of water and the bottom of the container has a diameter of 6.0 cm, what is the weight of the water in Newton's? Question 11 2 pts If the beaker holds 2.0...
The next three questions refer to a vertical cylindrical beaker holding water. The density of water is 1.0 g/cm3. The volume of a cylinder is LaTeX: \piπR2H, where R is the radius of the cylinder and H is the height. If the beaker holds 1.44 kg of water and the bottom of the container has a diameter of 6.0 cm, what is the weight of the water in Newton's? If the beaker holds 2.0 kg of water and the bottom...