Water pressure increases by approximately 1 Bar (14.5 psi) for every 10 meter of descent. The exact amount is dependent on local atmospheric pressure and whether it is fresh or salt water (salt water is lower density).
you would also need to do an experiment to find this out.
Water is not incompressible so as you go deeper you will need to correct for that.
(salt water is >higher< density - it is easier for people to float in it due to that)
the weight of the air on the surface of the water compresses the water to 14.7 psi 1 atm At 30 ft (2 atm) the weight of the water compresses everything below it At 60 ft (3 atm) the weight of the water compresses everything below it At 90 ft (4 atm) the weight of the water compresses everything below it and so it continues!
Pressure and depth are related in that pressure is proportional to depth. The equation to find pressure at a certain depth is p=dgh, where p is the pressure, d is the density, g is the acceleration of gravity and h is the depth.
The pressure inside an inverted hollow cylinder in water is equal to the pressure at the depth of the cylinder's centroid multiplied by the specific weight of water. To calculate it, use the formula: pressure = (specific weight of water) * (depth of centroid of cylinder).
The density of water increases with depth due to the increase in pressure. As water molecules are packed closer together under high pressure, the density of water increases. Therefore, in deep water where the pressure is higher, the density of water is also higher.
The velocity of water changes with depth due to variations in pressure and friction. Near the surface, water velocity is typically faster due to less friction, while deeper in the water column, velocity may decrease due to increased pressure from the weight of the water above. This change in velocity with depth is also influenced by factors such as the slope of the river or ocean floor and the density of the water.
Pressure due to a liquid increases with depth because of the weight of the liquid above it. The pressure in a liquid is the same at a given depth regardless of the shape or size of the container, as long as the depth is the same. The shape and size of the container would only affect the pressure at different depths in the liquid.
As depth increases, pressure also increases due to the weight of the water column above. Temperature affects pressure by influencing the density of a fluid; warm water is less dense and exerts less pressure than cold water at the same depth.
More depth equals more pressure, thus why ears pop when diving in water.
Pressure underwater is calculated by multiplying the depth of the water by the density of the fluid and the acceleration due to gravity. The formula is pressure depth x density x gravity. Factors that affect pressure underwater include the depth of the water, the density of the fluid, and the acceleration due to gravity.
it doesnt That is really bad answer
Water pressure increases as depth increases.
The relationship between water depth and pressure is linear. As water depth increases, the pressure exerted by the water also increases. This relationship is described by the hydrostatic pressure formula, which states that pressure is directly proportional to the depth of the fluid and the density of the fluid.
Resistance of water is probably defined as pressure being applied by water on objects and as it's stated in fluid mechanics books pressure increases as height decreases or depth increases, so simply the answer is "yes".
At 300 feet of water depth the pressure is about 130 psi
To calculate water pressure at a certain depth, you can use the formula: Pressure density of water x gravity x depth. The density of water is typically 1000 kg/m3, and gravity is 9.81 m/s2. Multiply these values by the depth in meters to find the water pressure in pascals.
Pressure depends on depth, not volume. Pressure increases with increasing depth due to the weight of the overlying fluid pressing down. Volume can affect pressure indirectly by changing the depth of the fluid column.
The total pressure of water is calculated by adding the atmospheric pressure to the pressure due to the depth of the water column using the formula: total pressure = atmospheric pressure + (density of water × acceleration due to gravity × depth of water).
As depth increases, water pressure also increases due to the weight of the water column above exerting a force downwards. The increase in pressure is approximately 1 atmosphere (14.7 pounds per square inch) for every 10 meters of depth.