Rain drop with a diameter of 2.0 mm falling from height of 3.5 km. Assuming that...

Calculate the speed a spherical rain drop would achieve falling from 4.2 km (a) in the...

Calculate the speed a spherical rain drop would achieve falling from 4.2 km (a) in the absence of air drag (b) with air drag. Take the size across of the drop to be 4.2 mm, the density to be 1.00×103??/?3 , and the surface area to be ??2 . Additionaly: the density of air is 1.21??/?3 , and the drag coefficient for the spherical drop is 0.45. a) In the absence of air drag b) with air drag

Calculate the speed (in m/s) a spherical rain drop would achieve falling from 4.10 km in...

Calculate the speed (in m/s) a spherical rain drop would achieve falling from 4.10 km in the absence of air drag and with air drag. Take the size across of the drop to be 5 mm, the density to be 1.00 ? 103 kg/m3, and the surface area to be ?r2. (Assume the density of air is 1.21 kg/m3.) (a)in the absence of air drag. (b) with air drag.

Calculate the velocity a spherical rain drop would achieve falling (taking downward as positive) from 4.2...

Calculate the velocity a spherical rain drop would achieve falling (taking downward as positive) from 4.2 km in the following situations. h = 4.2 km l = 4.8 mm d = 1.23 kg/m3 a Calculate the velocity in the absence of air drag in m/s. b  Calculate the velocity with air drag in m/s. Take the size across of the drop to be 4.8 mm, the density of air to be 1.23 kg/m3, the density of water to be 1000 kg/m3,...

Calculate the speed (in m/s) a spherical rain drop would achieve falling from 2.10 km in...

Calculate the speed (in m/s) a spherical rain drop would achieve falling from 2.10 km in the absence of air drag and with air drag. Take the size across of the drop to be 9 mm, the density to be 1.00 ✕ 103 kg/m3, and the surface area to be πr2. (Assume the density of air is 1.21 kg/m3.) (a) in the absence of air drag 202.985  m/s (correct) (b) with air drag 9.8687 m/s (incorrect)

Dust particles of diameter 0.06 mm and density 1.6 g/cm3 are unsettled during high winds and...

Dust particles of diameter 0.06 mm and density 1.6 g/cm3 are unsettled during high winds and rise to a height of 200 m by the time things calm down. Estimate how long it takes for the dust particles to fall back to the ground in still air at 1 atm and 30 C, and their velocity. Disregard the initial transient period during which the dust particles accelerate to their terminal velocity, and assume Stokes law (CD calculated at very low...

You drop a single coffee filter of mass 1.3 grams from a very tall building, and...

You drop a single coffee filter of mass 1.3 grams from a very tall building, and it takes 54 seconds to reach the ground. In a small fraction of that time the coffee filter reached terminal speed. (a) What was the upward force of the air resistance while the coffee filter was falling at terminal speed? Fair =____ N (b) Next you drop a stack of 4 of these coffee filters. What was the upward force of the air resistance...

Remember that pressure drop in piping vary as the diameter is changed, assuming the mass flow...

Remember that pressure drop in piping vary as the diameter is changed, assuming the mass flow rate is the same. you found that pressure drop is inversely proportional to diameter to the fifth power. You also know that velocity in the duct/pipe is inversely proportional to area or diameter squared, again for the same mass flow rate. Your water flow analysis is based on achieving a water flow velocity similar to the air velocity (24 ft/s), however the result for...

1. A car traveling 69 km/h is 247 m behind a truck traveling 93 km/h. How...

1. A car traveling 69 km/h is 247 m behind a truck traveling 93 km/h. How long will it take the car to reach the track? Calculate to one decimal 2.Suppose one of Napoleon cannons has a muzzle speed of 32m/s. It was aimed at 54 ◦ angle. What height can the cannon ball reach? Use g = 9.8 m/s2 Calculate to one decimal 3.A girl throws a rock horizontally, with a velocity of 13 m/s, from a bridge. It...

Calculate the limiting angle of resolution for the eye, assuming a pupil diameter of 1.75 mm,...

Calculate the limiting angle of resolution for the eye, assuming a pupil diameter of 1.75 mm, a wavelength of 520 nm in air, and an index of refraction for the eye of 1.33. ____ rad (b) What is the maximum distance from the eye at which two points separated by 14.00 cm could be resolved? ____m

An irrigation system has a 2.5 cm diameter hose, which shoots water at 60 ° from...

An irrigation system has a 2.5 cm diameter hose, which shoots water at 60 ° from the horizontal, at 5.5 m / s, and is placed on the ground. If we think that each droplet moves like a projectile, calculate: a- the maximum height that each droplet rises b- the time it takes to reach its maximum height c- the horizontal reach of the jet measured from the hose pistil