A truncated cone of length L cm traveling through a fluid at a speed of 8.38 m/s is shown. The narrow end of the cylinder has a diameter of 2.32cm, whereas the wider end has a diameter of 3.53 cm. The drag force acting on the cylinder is 24.6 newtons. V The drag force Fa acting on an object passing through a fluid is given by 1 F₁ = PATU² where A is the effective cross-sectional area of the object, I (the Greek letter gamma) is the drag coefficient, p is the density of the fluid, and v is the speed of the object. Calculate the drag coefficient I of the object if the fluid is water of density 1000.00 kg/m³. r=

A truncated cone of length ? cm traveling through a fluid at a speed of 8.38 m/s is shown. The narrow end of the cylinder has a diameter of 2.32cm, whereas the wider end has a diameter of 3.53 cm. The drag force acting on the cylinder is 24.6 newtons. The drag force ?? acting on an object passing through a fluid is given by ?d=12??Γ?2 where ? is the effective cross‑sectional area of the object, Γ (the Greek letter gamma) is the drag coefficient, ? is the density of the fluid, and ? is the speed of the object. Calculate the drag coefficient Γ of the object if the fluid is water of density 1000.00 kg/m3.

Transcribed Image Text:

A truncated cone of length L cm traveling through a fluid at a speed of 8.38 m/s is shown. The narrow end of the cylinder has a diameter of 2.32cm, whereas the wider end has a diameter of 3.53 cm. The drag force acting on the cylinder is 24.6 newtons. V The drag force Fa acting on an object passing through a fluid is given by 1 Fa - PAT² where A is the effective cross-sectional area of the object, I' (the Greek letter gamma) is the drag coefficient, p is the density of the fluid, and v is the speed of the object. Calculate the drag coefficient I of the object if the fluid is water of density 1000.00 kg/m³. T =